Article of clothing including bio-medical units

ABSTRACT

An article of clothing includes a clothing fabric and a plurality of bio-medical units integrated into the clothing fabric. A bio-medical includes a power harvesting module, a communication module, a processing module, a functional module, a die, and an IC package. The die supports the power harvesting module, the processing module, the communication module, and the functional module. The IC package houses the die and includes a mechanism for adhering to the clothing fabric.

CROSS REFERENCE TO RELATED PATENTS

The present U.S. Utility patent application claims priority pursuant to35 U.S.C. §120, as a continuation, to the following U.S. Utility patentapplication which is hereby incorporated herein by reference in itsentirety and made part of the present U.S. Utility patent applicationfor all purposes:

1. U.S. Utility patent application Ser. No. 13/029,969, entitled“ARTICLE OF CLOTHING INCLUDING BIO-MEDICAL UNITS,” filed Feb. 17, 2011,pending, which claims priority pursuant to 35 U.S.C. §120 as acontinuation-in-part to the following U.S. Utility patent applications,all of which are hereby incorporated herein by reference in theirentirety and made part of the present U.S. Utility patent applicationfor all purposes:a. U.S. Utility patent application Ser. No. 12/649,030, entitled,“ARTIFICIAL BODY PART INCLUDING BIO-MEDICAL UNITS”, having a filing dateof Dec. 29, 2009, pending;b. U.S. Utility patent application Ser. No. 12/829,279, entitled,“BIO-MEDICAL UNIT WITH IMAGE SENSOR FOR IN VIVO IMAGING”, having afiling date of Jul. 1, 2010, pending;c. U.S. Utility patent application Ser. No. 12/787,786, entitled,“COMMUNICATION DEVICE FOR COMMUNICATING WITH A BIO-MEDICAL UNIT”, havinga filing date of May 26, 2010, pending;d. U.S. Utility patent application Ser. No. 12/783,649, entitled,“BIO-MEDICAL UNIT WITH POWER HARVESTING MODULE AND RF COMMUNICATION”,having a filing date of May 20, 2010, pending;e. U.S. Utility patent application Ser. No. 12/848,830, entitled, “PAINMANAGEMENT BIO-MEDICAL UNIT”, having a filing date of Aug. 2, 2010,pending;2. all of which claim priority under 35 USC §119(e) to the followingU.S. Provisional patent application which is hereby incorporated hereinby reference in its entirety and made part of the present U.S. Utilitypatent application for all purposes:a. U.S. Provisional Ser. No. 61/247,060, entitled “BIO-MEDICAL UNIT ANDAPPLICATIONS THEREOF”, filed Sep. 30, 2009, now expired.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

NOT APPLICABLE

INCORPORATION-BY-REFERENCE OF MATERIAL SUBMITTED ON A COMPACT DISC

NOT APPLICABLE

BACKGROUND OF THE INVENTION

1. Technical Field of the Invention

This invention relates generally to medical equipment and moreparticularly to wireless medical equipment.

2. Description of Related Art

As is known, there is a wide variety of medical equipment that aids inthe diagnosis, monitoring, and/or treatment of patients' medicalconditions. For instances, there are diagnostic medical devices,therapeutic medical devices, life support medical devices, medicalmonitoring devices, medical laboratory equipment, etc. As specificexampled magnetic resonance imaging (MRI) devices produce images thatillustrate the internal structure and function of a body.

The advancement of medical equipment is in step with the advancements ofother technologies (e.g., radio frequency identification (RFID),robotics, etc.). Recently, RFID technology has been used for in vitrouse to store patient information for easy access. While such in vitroapplications have begun, the technical advancement in this area is inits infancy.

Therefore, a need exists for a bio-medical unit that has applicationswithin artificial body part implants.

BRIEF SUMMARY OF THE INVENTION

The present invention is directed to apparatus and methods of operationthat are further described in the following Brief Description of theDrawings, the Detailed Description of the Invention, and the claims.Other features and advantages of the present invention will becomeapparent from the following detailed description of the invention madewith reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING(S)

FIG. 1 is a diagram of an embodiment of a system in accordance with thepresent invention;

FIG. 2 is a diagram of another embodiment of a system in accordance withthe present invention;

FIG. 3 is a diagram of an embodiment of an artificial body partincluding one or more bio-medical units in accordance with the presentinvention;

FIG. 4 is a schematic block diagram of an embodiment of an artificialbody part in accordance with the present invention;

FIG. 5 is a diagram of another embodiment of a system in accordance withthe present invention;

FIG. 6 is a diagram of another embodiment of a system in accordance withthe present invention;

FIG. 7 is a diagram of another embodiment of a system in accordance withthe present invention;

FIG. 8 is a schematic block diagram of an embodiment of a bio-medicalunit in accordance with the present invention;

FIG. 9 is a schematic block diagram of an embodiment of a powerharvesting module in accordance with the present invention;

FIG. 10 is a schematic block diagram of another embodiment of a powerharvesting module in accordance with the present invention;

FIG. 11 is a schematic block diagram of another embodiment of a powerharvesting module in accordance with the present invention;

FIG. 12 is a schematic block diagram of another embodiment of a powerharvesting module in accordance with the present invention;

FIG. 13 is a schematic block diagram of an embodiment of a power boostmodule in accordance with the present invention;

FIG. 14 is a schematic block diagram of an embodiment of anelectromagnetic (EM) power harvesting module in accordance with thepresent invention;

FIG. 15 is a schematic block diagram of another embodiment of anelectromagnetic (EM) power harvesting module in accordance with thepresent invention;

FIG. 16 is a schematic block diagram of another embodiment of abio-medical unit in accordance with the present invention;

FIG. 17 is a diagram of another embodiment of a system in accordancewith the present invention;

FIG. 18 is a diagram of an example of a communication protocol within asystem in accordance with the present invention;

FIG. 19 is a diagram of another embodiment of a system in accordancewith the present invention;

FIG. 20 is a diagram of another example of a communication protocolwithin a system in accordance with the present invention;

FIG. 21 is a diagram of an embodiment of a bio-medical unit collectingaudio and/or ultrasound data in accordance with the present invention;

FIG. 22 is a diagram of another embodiment of a system in accordancewith the present invention;

FIG. 23 is a diagram of another embodiment of a system in accordancewith the present invention;

FIG. 24 is a diagram of an embodiment of a network of bio-medical unitsin accordance with the present invention;

FIG. 25 is a logic diagram of an embodiment of a method for bio-medicalunit communications in accordance with the present invention;

FIG. 26 is a diagram of an embodiment of a system including bio-medicalunits for physical therapy treatment in accordance with the presentinvention;

FIG. 27 is a diagram of an embodiment of an electromagnetic signalgenerating unit in accordance with the present invention;

FIG. 28 is a diagram of another embodiment of a bio-medical unit inaccordance with the present invention;

FIG. 29 is a diagram of an embodiment of an integrated circuit (IC) thatincludes a bio-medical unit in accordance with the present invention;

FIG. 30 is a diagram of an embodiment of an article of clothing thatincludes a plurality of bio-medical units in accordance with the presentinvention;

FIGS. 31 a and 31 b are logic diagrams of an embodiment of a method forcommunication with an article of clothing that includes a plurality ofbio-medical units in accordance with the present invention;

FIG. 32 is a diagram of an embodiment of a system including bio-medicalunits for medication control in accordance with the present invention;

FIGS. 33A and 33B are logic diagrams of an embodiment of a method forcontrolling and/or monitoring medication administration in accordancewith the present invention;

FIG. 34 is a diagram of an embodiment of a surgical fastener including abio-medical unit in accordance with the present invention;

FIG. 35 is a diagram of another embodiment of a surgical fastenerincluding a bio-medical unit in accordance with the present invention;

FIG. 36 is a diagram of another embodiment of a surgical fastenerincluding a bio-medical unit in accordance with the present invention;

FIG. 37 is a diagram of another embodiment of a surgical fastenerincluding a bio-medical unit in accordance with the present invention;

FIG. 38 is a diagram of an embodiment of a network of bio-medical unitsthat include MEMS robotics in accordance with the present invention;

FIG. 39 is a diagram of another embodiment of a network of bio-medicalunits that include MEMS robotics in accordance with the presentinvention;

FIG. 40 is a diagram of an embodiment of a bio-medical unit collectingimage data in accordance with the present invention;

FIG. 41 is a diagram of another embodiment of a network of bio-medicalunits communicating via light signaling in accordance with the presentinvention;

FIG. 42 is a diagram of an embodiment of a bio-medical unit collectingaudio and/or ultrasound data in accordance with the present invention;

FIG. 43 is a diagram of another embodiment of a network of bio-medicalunits communicating via audio and/or ultrasound signaling in accordancewith the present invention;

FIG. 44 is a diagram of an embodiment of a network of bio-medical unitscollecting ultrasound data in accordance with the present invention;

FIG. 45 is a diagram of an embodiment of a network of bio-medical unitsfor facilitating electrical stimulus treatment in accordance with thepresent invention;

FIG. 46 is a diagram of an embodiment of power conversion modules in abio-medical unit of FIG. 45 in accordance with the present invention;

FIG. 47 is a schematic block diagram of another embodiment of abio-medical unit in accordance with the present invention;

FIG. 48 is a schematic block diagram of an embodiment of a leaky antennaof the bio-medical unit of FIG. 47 in accordance with the presentinvention;

FIG. 49 is a diagram of an example of an antenna radiation pattern ofthe leaky antenna of FIG. 48 in accordance with the present invention;and

FIG. 50 is a diagram of another example of an antenna radiation patternof the leaky antenna of FIG. 48 in accordance with the presentinvention.

FIG. 51 is a diagram of an embodiment of a network of bio-medical unitswithin sutures in accordance with the present invention;

FIG. 52 is a diagram of an embodiment of a suture including abio-medical unit in accordance with the present invention;

FIG. 53 is a diagram of another embodiment of a suture including abio-medical unit in accordance with the present invention;

FIG. 54 is a diagram of another embodiment of a suture including abio-medical unit in accordance with the present invention;

FIG. 55 is a diagram of an embodiment of a bio-medical unit facilitatingpain blocking in accordance with the present invention;

FIG. 56 is a diagram of an embodiment of a bio-medical unit determiningrelative distance using Doppler shifting in accordance with the presentinvention;

FIG. 57 is a diagram of an example of determining relative distanceusing Doppler shifting in accordance with the present invention;

FIG. 58 is a diagram of an example of determining vibrations usingDoppler shifting and ultrasound in accordance with the presentinvention;

FIG. 59 is a diagram of an embodiment of a bio-medical unit including acontrolled release module in accordance with the present invention;

FIG. 60 is a diagram of an embodiment of a controlled release module inaccordance with the present invention;

FIG. 61 is a diagram of an embodiment of a system of bio-medical unitsfor controlled release of a medication in accordance with the presentinvention;

FIG. 62 is a diagram of an embodiment of a bio-medical unit includingsampling modules in accordance with the present invention;

FIG. 63 is a logic diagram of an embodiment of a method for bio-medicalunit communications in accordance with the invention;

FIG. 64 is a logic diagram of an embodiment of a method for MMWcommunications within a MRI sequence in accordance with the invention;

FIG. 65 is a logic diagram of an embodiment of a method for processingof MRI signals in accordance with the present invention;

FIG. 66 is a logic diagram of an embodiment of a method forcommunication utilizing MRI signals in accordance with the presentinvention;

FIG. 67 is a logic diagram of another embodiment of a method forbio-medical unit communications in accordance with the invention; and

FIG. 68 is a logic diagram of an embodiment of a method for coordinationof bio-medical unit task execution in accordance with the presentinvention.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 is a diagram of an embodiment of a system that includes aplurality of bio-medical units 10 embedded within a body and/or placedon the surface of the body to facilitate diagnosis, treatment, and/ordata collections. Each of the bio-medical units 10 is a passive device(e.g., it does not include a power source (e.g., a battery)) and, assuch, includes a power harvesting module. The bio-medical units 10 mayalso include one or more of memory, a processing module, and functionalmodules. Alternatively, or in addition to, each of the bio-medical units10 may include a rechargeable power source.

In operation, a transmitter 12 emits electromagnetic signals 16 thatpass through the body and are received by a receiver 14. The transmitter12 and receiver 14 may be part of a piece of medical diagnosticequipment (e.g., magnetic resonance imaging (MRI), X-ray, etc.) orindependent components for stimulating and communicating with thenetwork of bio-medical units in and/or on a body. One or more of thebio-medical units 10 receives the transmitted electromagnetic signals 16and generates a supply voltage therefrom. Examples of this will bedescribed in greater detail with reference to FIGS. 8-12.

Embedded within the electromagnetic signals 16 (e.g., radio frequency(RF) signals, millimeter wave (MMW) signals, MRI signals, etc.) or viaseparate signals, the transmitter 12 communicates with one or more ofthe bio-medical units 10. For example, the electromagnetic signals 16may have a frequency in the range of a few MHz to 900 MHz and thecommunication with the bio-medical units 10 is modulated on theelectromagnetic signals 16 at a much higher frequency (e.g., 5 GHz to300 GHz). As another example, the communication with the bio-medicalunits 10 may occur during gaps (e.g., per protocol of medical equipmentor injected for communication) of transmitting the electromagneticsignals 16. As another example, the communication with the bio-medicalunits 10 occurs in a different frequency band and/or using a differenttransmission medium (e.g., use RF or MMW signals when the magnetic fieldof the electromagnetic signals are dominate, use ultrasound signals whenthe electromagnetic signals 16 are RF and/or MMW signals, etc.).

One or more of the bio-medical units 10 receives the communicationsignals 18 and processes them accordingly. The communication signals 18may be instructions to collect data, to transmit collected data, to movethe unit's position in the body, to perform a function, to administer atreatment, etc. If the received communication signals 18 require aresponse, the bio-medical unit 10 prepares an appropriate response andtransmits it to the receiver 14 using a similar communication conventionused by the transmitter 12.

FIG. 2 is a diagram of another embodiment of a system that includes aplurality of bio-medical units 10 embedded within a body and/or placedon the surface of the body to facilitate diagnosis, treatment, and/ordata collections. Each of the bio-medical units 10 is a passive deviceand, as such, includes a power harvesting module. The bio-medical units10 may also include one or more of memory, a processing module, andfunctional modules. In this embodiment, the person is placed in an MRImachine (fixed or portable) that generates a magnetic field 26 throughwhich the MRI transmitter 20 transmits MRI signals 28 to the MRIreceiver 22.

One or more of the bio-medical units 10 powers itself by harvestingenergy from the magnetic field 26 or changes thereof as produced bygradient coils, from the magnetic fields of the MRI signals 28, from theelectrical fields of the MRI signals 28, and/or from the electromagneticaspects of the MRI signals 28. A unit 10 converts the harvested energyinto a supply voltage that supplies other components of the unit (e.g.,a communication module, a processing module, memory, a functionalmodule, etc.).

A communication device 24 communicates data and/or controlcommunications 30 with one or more of the bio-medical units 10 over oneor more wireless links. The communication device 24 may be a separatedevice from the MRI machine or integrated into the MRI machine. Forexample, the communication device 24, whether integrated or separate,may be a cellular telephone, a computer with a wireless interface (e.g.,a WLAN station and/or access point, Bluetooth, a proprietary protocol,etc.). A wireless link may be one or more frequencies in the ISM band,in the 60 GHz frequency band, the ultrasound frequency band, and/orother frequency bands that supports one or more communication protocols(e.g., data modulation schemes, beamforming, RF or MMW modulation,encoding, error correction, etc.).

The composition of the bio-medical units 10 includes non-ferromagneticmaterials (e.g., paramagnetic or diamagnetic) and/or metal alloys thatare minimally affected by an external magnetic field 26. In this regard,the units harvest power from the MRI signals 28 and communicate using RFand/or MMW electromagnetic signals with negligible chance ofencountering the projectile or missile effect of implants that includeferromagnetic materials.

FIG. 3 is a diagram of an embodiment of an artificial body part 32including one or more bio-medical units 10 that may be surgicallyimplanted into a body. The artificial body part 32 may be a pace maker,a breast implant, a joint replacement, an artificial bone, splints,fastener devices (e.g., screws, plates, pins, sutures, etc.), artificialorgan, etc. The artificial body part 32 may be permanently embedded inthe body or temporarily embedded into the body.

FIG. 4 is a schematic block diagram of an embodiment of an artificialbody part 32 that includes one or more bio-medical units 10. Forinstance, one bio-medical unit 10 may be used to detect infections, thebody's acceptance of the artificial body part 32, measure localized bodytemperature, monitor performance of the artificial body part 32, and/ordata gathering for other diagnostics. Another bio-medical unit 10 may beused for deployment of treatment (e.g., disperse medication, applyelectrical stimulus, apply RF radiation, apply laser stimulus, etc.).Yet another bio-medical unit 10 may be used to adjust the position ofthe artificial body part 32 and/or a setting of the artificial body part32. For example, a bio-medical unit 10 may be used to mechanicallyadjust the tension of a splint, screws, etc. As another example, abio-medical unit 10 may be used to adjust an electrical setting of theartificial body part 32.

FIG. 5 is a diagram of another embodiment of a system that includes aplurality of bio-medical units 10 and one or more communication devices24 coupled to a wide area network (WAN) communication device 34 (e.g., acable modem, DSL modem, base station, access point, hot spot, etc.). TheWAN communication device 34 is coupled to a network 42 (e.g., cellulartelephone network, internet, etc.), which has coupled to it a pluralityof remote monitors 36, a plurality of databases 40, and a plurality ofcomputers 38. The communication device 24 includes a processing moduleand a wireless transceiver module (e.g., one or more transceivers) andmay function similarly to communication module 48 as described in FIG.8,

In this system, one or more bio-medical units 10 are implanted in, oraffixed to, a host body (e.g., a person, an animal, genetically growntissue, etc.). As previously discussed and will be discussed in greaterdetail with reference to one or more of the following figures, abio-medical unit includes a power harvesting module, a communicationmodule, and one or more functional modules. The power harvesting moduleoperable to produce a supply voltage from a received electromagneticpower signal (e.g., the electromagnetic signal 16 of FIGS. 1 and 2, theMRI signals of one or more the subsequent figures). The communicationmodule and the at least one functional module are powered by the supplyvoltage.

In an example of operation, the communication device 24 (e.g.,integrated into an MRI machine, a cellular telephone, a computer with awireless interface, etc.) receives a downstream WAN signal from thenetwork 42 via the WAN communication device 34. The downstream WANsignal may be generated by a remote monitoring device 36, a remotediagnostic device (e.g., computer 38 performing a remote diagnosticfunction), a remote control device (e.g., computer 38 performing aremote control function), and/or a medical record storage device (e.g.,database 40).

The communication device 24 converts the downstream WAN signal into adownstream data signal. For example, the communication device 24 mayconvert the downstream WAN signal into a symbol stream in accordancewith one or more wireless communication protocols (e.g., GSM, CDMA,WCDMA, HSUPA, HSDPA, WiMAX, EDGE, GPRS, IEEE 802.11, Bluetooth, ZigBee,universal mobile telecommunications system (UMTS), long term evolution(LTE), IEEE 802.16, evolution data optimized (EV-DO), etc.). Thecommunication device 24 may convert the symbol stream into thedownstream data signal using the same or a different wirelesscommunication protocol.

Alternatively, the communication device 24 may convert the symbol streaminto data that it interprets to determine how to structure thecommunication with the bio-medical unit 10 and/or what data (e.g.,instructions, commands, digital information, etc.) to include in thedownstream data signal. Having determined how to structure and what toinclude in the downstream data signal, the communication device 24generates the downstream data signal in accordance with one or morewireless communication protocols. As yet another alternative, thecommunication device 24 may function as a relay, which provides thedownstream WAN signal as the downstream data signal to the one or morebio-medical units 10.

When the communication device 24 has (and/or is processing) thedownstream data signal to send to the bio-medical unit, it sets up acommunication with the bio-medical unit. The set up may includeidentifying the particular bio-medical unit(s), determining thecommunication protocol used by the identified bio-medical unit(s),sending a signal to an electromagnetic device (e.g., MRI device, etc.)to request that it generates the electromagnetic power signal to powerthe bio-medical unit, and/or initiate a communication in accordance withthe identified communication protocol. As an alternative to requesting aseparate electromagnetic device to create the electromagnetic powersignal, the communication device may include an electromagnetic deviceto create the electromagnetic power signal.

Having set up the communication, the communication device 24 wirelesslycommunicates the downstream data signal to the communication module ofthe bio-medical unit 10. The functional module of the bio-medical unit10 processes the downstream data contained in the downstream data signalto perform a bio-medical functional, to store digital informationcontained in the downstream data, to administer a treatment (e.g.,administer a medication, apply laser stimulus, apply electricalstimulus, etc.), to collect a sample (e.g., blood, tissue, cell, etc.),to perform a micro electro-mechanical function, and/or to collect data.For example, the bio-medical function may include capturing a digitalimage, capturing a radio frequency (e.g., 300 MHz to 300 GHz) radarimage, an ultrasound image, a tissue sample, and/or a measurement (e.g.,blood pressure, temperature, pulse, blood-oxygen level, blood sugarlevel, etc.).

When the downstream data requires a response, the functional moduleperforms a bio-medical function to produce upstream data. Thecommunication module converts the upstream data into an upstream datasignal in accordance with the one or more wireless protocols. Thecommunication device 24 converts the upstream data signal into anupstream wide area network (WAN) signal and transmits it to a remotediagnostic device, a remote control device, and/or a medical recordstorage device. In this manner, a person(s) operating the remotemonitors 36 may view images and/or the data 30 gathered by thebio-medical units 10. This enables a specialist to be consulted withoutrequiring the patient to travel to the specialist's office.

In another example of operation, one or more of the computers 38 maycommunicate with the bio-medical units 10 via the communication device24, the WAN communication device 34, and the network 42. In thisexample, the computer 36 may provide commands 30 to one or more of thebio-medical units 10 to gather data, to dispense a medication, to moveto a new position in the body, to perform a mechanical function (e.g.,cut, grasp, drill, puncture, stitch, patch, etc.), etc. As such, thebio-medical units 10 may be remotely controlled via one or more of thecomputers 36.

In another example of operation, one or more of the bio-medical units 10may read and/or write data from or to one or more of the databases 40.For example, data (e.g., a blood sample analysis) generated by one ormore of the bio-medical units 10 may be written to one of the databases40. The communication device 24 and/or one of the computers 36 maycontrol the writing of data to or the reading of data from thedatabase(s) 40. The data may further include medical records, medicalimages, prescriptions, etc.

FIG. 6 is a diagram of another embodiment of a system that includes aplurality of bio-medical units 10. In this embodiment, the bio-medicalunits 10 can communicate with each other directly and/or communicatewith the communication device 24 directly. The communication medium maybe an infrared channel(s), an RF channel(s), a MMW channel(s), and/orultrasound. The units may use a communication protocol such as tokenpassing, carrier sense, time division multiplexing, code divisionmultiplexing, frequency division multiplexing, etc.

FIG. 7 is a diagram of another embodiment of a system that includes aplurality of bio-medical units 10. In this embodiment, one of thebio-medical units 44 functions as an access point for the other units.As such, the designated unit 44 routes communications between the units10 and between one or more units 10 and the communication device 24. Thecommunication medium may be an infrared channel(s), an RF channel(s), aMMW channel(s), and/or ultrasound. The units 10 may use a communicationprotocol such as token passing, carrier sense, time divisionmultiplexing, code division multiplexing, frequency divisionmultiplexing, etc.

FIG. 8 is a schematic block diagram of an embodiment of a bio-medicalunit 10 that includes a power harvesting module 46, a communicationmodule 48, a processing module 50, memory 52, and one or more functionalmodules 54. The processing module 50 may be a single processing deviceor a plurality of processing devices. Such a processing device may be amicroprocessor, micro-controller, digital signal processor,microcomputer, central processing unit, field programmable gate array,programmable logic device, state machine, logic circuitry, analogcircuitry, digital circuitry, and/or any device that manipulates signals(analog and/or digital) based on hard coding of the circuitry and/oroperational instructions. The processing module 50 may have anassociated memory 52 and/or memory element, which may be a single memorydevice, a plurality of memory devices, and/or embedded circuitry of theprocessing module. Such a memory device 52 may be a read-only memory,random access memory, volatile memory, non-volatile memory, staticmemory, dynamic memory, flash memory, cache memory, and/or any devicethat stores digital information. Note that if the processing module 50includes more than one processing device, the processing devices may becentrally located (e.g., directly coupled together via a wired and/orwireless bus structure) or may be distributedly located (e.g., cloudcomputing via indirect coupling via a local area network and/or a widearea network). Further note that when the processing module 50implements one or more of its functions via a state machine, analogcircuitry, digital circuitry, and/or logic circuitry, the memory and/ormemory element storing the corresponding operational instructions may beembedded within, or external to, the circuitry comprising the statemachine, analog circuitry, digital circuitry, and/or logic circuitry.Still further note that, the memory element stores, and the processingmodule executes, hard coded and/or operational instructionscorresponding to at least some of the steps and/or functions illustratedin FIGS. 1-29.

The power harvesting module 46 may generate one or more supply voltages56 (Vdd) from a power source signal (e.g., one or more of MRIelectromagnetic signals 16, magnetic fields 26, RF signals, MMW signals,ultrasound signals, light signals, and body motion). The powerharvesting module 46 may be implemented as disclosed in U.S. Pat. No.7,595,732 to generate one or more supply voltages from an RF signal. Thepower harvesting module 46 may be implemented as shown in one or moreFIGS. 9-11 to generate one or more supply voltages 56 from an MRI signal28 and/or magnetic field 26. The power harvesting module 46 may beimplemented as shown in FIG. 12 to generate one or more supply voltage56 from body motion. Regardless of how the power harvesting modulegenerates the supply voltage(s), the supply voltage(s) are used to powerthe communication module 48, the processing module 50, the memory 52,and/or the functional modules 54.

In an example of operation, a receiver section of the communicationmodule 48 receives an inbound wireless communication signal 60 andconverts it into an inbound symbol stream. For example, the receiversection amplifies an inbound wireless (e.g., RF or MMW) signal 60 toproduce an amplified inbound RF or MMW signal. The receiver section maythen mix in-phase (I) and quadrature (Q) components of the amplifiedinbound RF or MMW signal with in-phase and quadrature components of alocal oscillation to produce a mixed I signal and a mixed Q signal. Themixed I and Q signals are combined to produce an inbound symbol stream.In this embodiment, the inbound symbol may include phase information(e.g., +/−Δθ [phase shift] and/or θ(t) [phase modulation]) and/orfrequency information (e.g., +/−Δf [frequency shift] and/or f(t)[frequency modulation]). In another embodiment and/or in furtherance ofthe preceding embodiment, the inbound RF or MMW signal includesamplitude information (e.g., +/−ΔA [amplitude shift] and/or A(t)[amplitude modulation]). To recover the amplitude information, thereceiver section includes an amplitude detector such as an envelopedetector, a low pass filter, etc.

The processing module 50 converts the inbound symbol stream into inbounddata and generates a command message based on the inbound data. Thecommand message may instruction one or more of the functional modules toperform one or more electro-mechanical functions of gathering data,dispensing a medication, moving to a new position in the body,performing a mechanical function (e.g., cut, grasp, drill, puncture,stitch, patch, etc.), dispensing a treatment, collecting a biologicalsample, etc.

To convert the inbound symbol stream into the inbound data (e.g., voice,text, audio, video, graphics, etc.), the processing module 50 mayperform one or more of: digital intermediate frequency to basebandconversion, time to frequency domain conversion, space-time-blockdecoding, space-frequency-block decoding, demodulation, frequency spreaddecoding, frequency hopping decoding, beamforming decoding,constellation demapping, deinterleaving, decoding, depuncturing, and/ordescrambling. Such a conversion is typically prescribed by one or morewireless communication standards (e.g., GSM, CDMA, WCDMA, HSUPA, HSDPA,WiMAX, EDGE, GPRS, IEEE 802.11, Bluetooth, ZigBee, universal mobiletelecommunications system (UMTS), long term evolution (LTE), IEEE802.16, evolution data optimized (EV-DO), etc.).

The processing module 50 provides the command message to one or more ofthe micro-electromechanical functional modules 54. The functional module54 performs an electro-mechanical function within a hosting body inaccordance with the command message. Such an electro-mechanical functionincludes at least one of data gathering, motion, repairs, dispensingmedication, biological sampling, diagnostics, applying laser treatment,applying ultrasound treatment, grasping, sawing, drilling, providing anelectronic stimulus etc. Note that the functional modules 54 may beimplemented using nanotechnology and/or microelectronic mechanicalsystems (MEMS) technology.

When requested per the command message (e.g. gather data and report thedata), the micro electro-mechanical functional module 54 generates anelectro-mechanical response based on the performing theelectro-mechanical function. For example, the response may be data(e.g., heart rate, blood sugar levels, temperature, etc.), a biologicalsample (e.g., blood sample, tissue sample, etc.), acknowledgement ofperforming the function (e.g., acknowledge a software update, storing ofdata, etc.), and/or any appropriate response. The microelectro-mechanical functional module 54 provides the response to theprocessing module 50.

The processing module 50 converts the electro-mechanical response intoan outbound symbol stream, which may be done in accordance with one ormore wireless communication standards (e.g., GSM, CDMA, WCDMA, HSUPA,HSDPA, WiMAX, EDGE, GPRS, IEEE 802.11, Bluetooth, ZigBee, universalmobile telecommunications system (UMTS), long term evolution (LTE), IEEE802.16, evolution data optimized (EV-DO), etc.). Such a conversionincludes one or more of: scrambling, puncturing, encoding, interleaving,constellation mapping, modulation, frequency spreading, frequencyhopping, beamforming, space-time-block encoding, space-frequency-blockencoding, frequency to time domain conversion, and/or digital basebandto intermediate frequency conversion.

A transmitter section of the communication module 48 converts anoutbound symbol stream into an outbound RF or MMW signal 60 that has acarrier frequency within a given frequency band (e.g., 900 MHz, 2.5 GHz,5 GHz, 57-66 GHz, etc.). In an embodiment, this may be done by mixingthe outbound symbol stream with a local oscillation to produce anup-converted signal. One or more power amplifiers and/or power amplifierdrivers amplifies the up-converted signal, which may be RF or MMWbandpass filtered, to produce the outbound RF or MMW signal 60. Inanother embodiment, the transmitter section includes an oscillator thatproduces an oscillation. The outbound symbol stream provides phaseinformation (e.g., +/−Δθ [phase shift] and/or θ(t) [phase modulation])that adjusts the phase of the oscillation to produce a phase adjusted RFor MMW signal, which is transmitted as the outbound RF signal 60. Inanother embodiment, the outbound symbol stream includes amplitudeinformation (e.g., A(t) [amplitude modulation]), which is used to adjustthe amplitude of the phase adjusted RF or MMW signal to produce theoutbound RF or MMW signal 60.

In yet another embodiment, the transmitter section includes anoscillator that produces an oscillation. The outbound symbol providesfrequency information (e.g., +/−Δf [frequency shift] and/or f(t)[frequency modulation]) that adjusts the frequency of the oscillation toproduce a frequency adjusted RF or MMW signal, which is transmitted asthe outbound RF or MMW signal 60. In another embodiment, the outboundsymbol stream includes amplitude information, which is used to adjustthe amplitude of the frequency adjusted RF or MMW signal to produce theoutbound RF or MMW signal 60. In a further embodiment, the transmittersection includes an oscillator that produces an oscillation. Theoutbound symbol provides amplitude information (e.g., +/−ΔA [amplitudeshift] and/or A(t) [amplitude modulation) that adjusts the amplitude ofthe oscillation to produce the outbound RF or MMW signal 60.

Note that the bio-medical unit 10 may be encapsulated by an encapsulate58 that is non-toxic to the body. For example, the encapsulate 58 may bea silicon based product, a non-ferromagnetic metal alloy (e.g.,stainless steel), etc. As another example, the encapsulate 58 mayinclude a spherical shape and have a ferromagnetic liner that shieldsthe unit from a magnetic field and to offset the forces of the magneticfield. Further note that the bio-medical unit 10 may be implemented on asingle die that has an area of a few millimeters or less. The die may befabricated in accordance with CMOS technology, Gallium-Arsenidetechnology, and/or any other integrated circuit die fabrication process.

FIG. 9 is a schematic block diagram of an embodiment of a powerharvesting module 46 that includes an array of on-chip air coreinductors 64, a rectifying circuit 66, capacitors, and a regulationcircuit 68. The inductors 64 may each having an inductance of a fewnano-Henries to a few micro-Henries and may be coupled in series, inparallel, or a series parallel combination.

In an example of operation, the MRI transmitter 20 transmits MRI signals28 at a frequency of 3-45 MHz at a power level of up to 35 KWatts. Theair core inductors 64 are electromagnetically coupled to generate avoltage from the magnetic and/or electric field generated by the MRIsignals 28. Alternatively or in addition to, the air core inductors 64may generate a voltage from the magnetic field 26 and changes thereofproduced by the gradient coils. The rectifying circuit 66 rectifies theAC voltage produced by the inductors to produce a first DC voltage. Theregulation circuit generates one or more desired supply voltages 56 fromthe first DC voltage.

The inductors 64 may be implemented on one more metal layers of the dieand include one or more turns per layer. Note that trace thickness,trace length, and other physical properties affect the resultinginductance.

FIG. 10 is a schematic block diagram of another embodiment of a powerharvesting module 46 that includes a plurality of on-chip air coreinductors 70, a plurality of switching units (S), a rectifying circuit66, a capacitor, and a switch controller 72. The inductors 70 may eachhaving an inductance of a few nano-Henries to a few micro-Henries andmay be coupled in series, in parallel, or a series parallel combination.

In an example of operation, the MRI transmitter 20 transmits MRI signals28 at a frequency of 3-45 MHz at a power level of up to 35 KWatts. Theair core inductors 70 are electromagnetically coupled to generate avoltage from the magnetic and/or electric field generated by the MRIsignals 28. The switching module 72 engages the switches via controlsignals 74 to couple the inductors 70 in series and/or parallel togenerate a desired AC voltage. The rectifier circuit 66 and thecapacitor(s) convert the desired AC voltage into the one or more supplyvoltages 56.

FIG. 11 is a schematic block diagram of another embodiment of a powerharvesting module 46 that includes a plurality of Hall effect devices76, a power combining module 78, and a capacitor(s). In an example ofoperation, the Hall effect devices 76 generate a voltage based on theconstant magnetic field (H) and/or a varying magnetic field. The powercombining module 78 (e.g., a wire, a switch network, a transistornetwork, a diode network, etc.) combines the voltages of the Hall effectdevices 76 to produce the one or more supply voltages 56.

FIG. 12 is a schematic block diagram of another embodiment of a powerharvesting module 46 that includes a plurality of piezoelectric devices82, a power combining module 78, and a capacitor(s). In an example ofoperation, the piezoelectric devices 82 generate a voltage based on bodymovement, ultrasound signals, movement of body fluids, etc. The powercombining module 78 (e.g., a wire, a switch network, a transistornetwork, a diode network, etc.) combines the voltages of the Hall effectdevices 82 to produce the one or more supply voltages 56. Note that thepiezoelectric devices 82 may include one or more of a piezoelectricmotor, a piezoelectric actuator, a piezoelectric sensor, and/or apiezoelectric high voltage device.

The various embodiments of the power harvesting module 46 may becombined to generate more power, more supply voltages, etc. For example,the embodiment of FIG. 9 may be combined with one or more of theembodiments of FIGS. 11 and 12.

FIG. 13 is a schematic block diagram of an embodiment of a power boostmodule 84 that harvests energy from MRI signals 28 and converts theenergy into continuous wave (CW) RF (e.g., up to 3 GHz) and/or MMW(e.g., up to 300 GHz) signals 92 to provide power to the implantedbio-medical units 10. The power boost module 84 sits on the body of theperson under test or treatment and includes an electromagnetic powerharvesting module 86 and a continuous wave generator 88. In such anembodiment, the power boosting module 84 can recover significantly moreenergy than a bio-medical unit 10 since it can be significantly larger.For example, a bio-medical unit 10 may have an area of a few millimeterssquared while the power boosting module 84 may have an area of a few totens of centimeters squared.

FIG. 14 is a schematic block diagram of an embodiment of anelectromagnetic (EM) power harvesting module 86 that includes inductors,diodes (or transistors) and a capacitor. The inductors may each be a fewmilli-Henries such that the power boost module can deliver up to 10's ofmilli-watts of power.

FIG. 15 is a schematic block diagram of another embodiment of anelectromagnetic (EM) power harvesting module 86 that includes aplurality of Hall effect devices 76, a power combining module 78, and acapacitor. This functions as described with reference to FIG. 11, butthe Hall effect devices 76 can be larger such that more power can beproduced. Note that the EM power harvesting module 86 may include acombination of the embodiment of FIG. 14 and the embodiment of FIG. 15.

FIG. 16 is a schematic block diagram of another embodiment of abio-medical unit 10 that includes a power harvesting module 46, acommunication module 48, a processing module 50, memory 52, and mayinclude one or more functional modules 54 and/or a Hall effectcommunication module 116. The communication module 48 may include one ormore of an ultrasound transceiver 118, an electromagnetic transceiver122, an RF and/or MMW transceiver 120, and a light source (LED)transceiver 124. Note that examples of the various types ofcommunication modules 48 will be described in greater detail withreference to one or more of FIGS. 14-49.

The one or more functional modules 54 may perform a repair function, animaging function, and/or a leakage detection function, which may utilizeone or more of a motion propulsion module 96, a camera module 98, asampling robotics module 100, a treatment robotics module 102, anaccelerometer module 104, a flow meter module 106, a transducer module108, a gyroscope module 110, a high voltage generator module 112, acontrol release robotics module 114, and/or other functional modulesdescribed with reference to one or more other figures. The functionalmodules 54 may be implemented using MEMS technology and/ornanotechnology. For example, the camera module 98 may be implemented asa digital image sensor in MEMS technology.

The Hall effect communication module 116 utilizes variations in themagnetic field and/or electrical field to produce a plus or minusvoltage, which can be encoded to convey information. For example, thecharge applied to one or more Hall effect devices 76 may be varied toproduce the voltage change. As another example, an MRI transmitter 20and/or gradient unit may modulate a signal on the magnetic field 26 itgenerates to produce variations in the magnetic field 26.

FIG. 17 is a diagram of another embodiment of a system that includes oneor more bio-medical units 10, a transmitter unit 126, and a receiverunit 128. Each of the bio-medical units 10 includes a power harvestingmodule 46, a MMW transceiver 138, a processing module 50, and memory 52.The transmitter unit 126 includes a MRI transmitter 130 and a MMWtransmitter 132. The receiver unit 128 includes a MRI receiver 134 and aMMW receiver 136. Note that the MMW transmitter 132 and MMW receiver 136may be in the same unit (e.g., in the transmitter unit, in the receiverunit, or housed in a separate device).

In an example of operation, the bio-medical unit 10 recovers power fromthe electromagnetic (EM) signals 146 transmitted by the MRI transmitter130 and communicates via MMW signals 148-150 with the MMW transmitter132 and MMW receiver 136. The MRI transmitter 130 may be part of aportable MRI device, may be part of a full sized MRI machine, and/orpart of a separate device for generating EM signals 146 for powering thebio-medical unit 10.

FIG. 18 is a diagram of an example of a communication protocol withinthe system of FIG. 17. In this diagram, the MRI transmitter 20 transmitsRF signals 152, which have a frequency in the range of 3-45 MHz, atvarious intervals with varying signal strengths. The power harvestingmodule 46 of the bio-medical units 10 may use these signals to generatepower for the bio-medical unit 10.

In addition to the MRI transmitter 20 transmitting its signal, aconstant magnetic field and various gradient magnetic fields 154-164 arecreated (one or more in the x dimension Gx, one or more in the ydimension Gy, and one or more in the z direction Gz). The powerharvesting module 46 of the bio-medical unit 10 may further use theconstant magnetic field and/or the varying magnetic fields 154-164 tocreate power for the bio-medical unit 10.

During non-transmission periods of the cycle, the bio-medical unit 10may communicate 168 with the MMW transmitter 132 and/or MMW receiver136. In this regard, the bio-medical unit 10 alternates from generatingpower to MMW communication in accordance with the conventionaltransmission-magnetic field pattern of an MRI machine.

FIG. 19 is a diagram of another embodiment of a system includes one ormore bio-medical units 10, a transmitter unit 126, and a receiver unit128. Each of the bio-medical units 10 includes a power harvesting module46, an EM transceiver 174, a processing module 50, and memory 52. Thetransmitter unit 126 includes a MRI transmitter 130 and electromagnetic(EM) modulator 170. The receiver unit 128 includes a MRI receiver 134and a EM demodulator 172. The transmitter unit 126 and receiver unit 128may be part of a portable MRI device, may be part of a full sized MRImachine, or part of a separate device for generating EM signals forpowering the bio-medical unit 10.

In an example of operation, the MRI transmitter 130 generates anelectromagnetic signal that is received by the EM modulator 170. The EMmodulator 170 modulates a communication signal on the EM signal toproduce an inbound modulated EM signal 176. The EM modulator 170 maymodulate (e.g., amplitude modulation, frequency modulation, amplitudeshift keying, frequency shift keying, etc.) the magnetic field and/orelectric field of the EM signal. In another embodiment, the EM modulator170 may modulate the magnetic fields produced by the gradient coils toproduce the inbound modulated EM signals 176.

The bio-medical unit 10 recovers power from the modulatedelectromagnetic (EM) signals. In addition, the EM transceiver 174demodulates the modulated EM signals 178 to recover the communicationsignal. For outbound signals, the EM transceiver 174 modulates anoutbound communication signal to produce outbound modulated EM signals180. In this instance, the EM transceiver 174 is generating an EM signalthat, in air, is modulated on the EM signal transmitted by thetransmitter unit 126. In one embodiment, the communication in thissystem is half duplex such that the modulation of the inbound andoutbound communication signals is at the same frequency. In anotherembodiment, the modulation of the inbound and outbound communicationsignals are at different frequencies to enable full duplexcommunication.

FIG. 20 is a diagram of another example of a communication protocolwithin the system of FIG. 19. In this diagram, the MRI transmitter 20transmits RF signals 152, which have a frequency in the range of 3-45MHz, at various intervals with varying signal strengths. The powerharvesting module 46 of the bio-medical units 10 may use these signalsto generate power for the bio-medical unit 10.

In addition to the MRI transmitter 20 transmitting its signal, aconstant magnetic field and various gradient magnetic fields are created154-164 (one or more in the x dimension Gx, one or more in the ydimension Gy, and one or more in the z direction Gz). The powerharvesting module 46 of the bio-medical unit 10 may further use theconstant magnetic field and/or the varying magnetic fields 154-164 tocreate power for the bio-medical unit 10.

During the transmission periods of the cycle, the bio-medical unit 10may communicate via the modulated EM signals 182. In this regard, thebio-medical unit 10 generates power and communicates in accordance withthe conventional transmission-magnetic field pattern of an MRI machine.

FIG. 21 is a diagram of another embodiment of a system that includes oneor more bio-medical units 10, a service provider's communication device184, a WAN communication device 34, a service provider's computer 186, anetwork 42, one or more databases 40, and a server 188. The bio-medicalunit 10 includes a power harvesting module 46, a processing module 50,memory 52, and a MMW transceiver 138. The memory is storing URL data forthe patient 190. Note that the bio-medical unit 10 may be implanted inthe patient, on the patient's body, or on the patient's person (e.g., ina medical tag, a key chain, etc.).

The URL data 192 includes one or more URLs that identify locations ofthe patient's medical records. For example, one URL may be for thepatient's prescription records, another may be for hospitalizations,another for general office visits, etc. In this regard, the bio-medicalunit is an index to easily access the patient's medical history.

For a service provider to access the patient's medical records, or aportion thereof, the service provider's communication device 184retrieves the URL(s) 192 from the bio-medical unit. This may be done aspreviously discussed. The communication device 184 generates a requestto access the patient's information, where the request includes theURL(s) 192, the service provider's ID, and a data request. The requestis provided, via the WAN device 34 and the network 42, to the server188.

The server 188 processes 198 the request. If the service provider isauthenticated and the request is valid, the server issues a dataretrieval message to the one or more databases identified by the URL(s)192. The addressed database(s) 40 retrieves the data and provides it viathe network 42 and the WAN device 34 to the service provider's computer184.

FIG. 22 is a diagram of another embodiment of a system that includes oneor more bio-medical units 10, the patient's cell phone 200, a WANcommunication device 34, a service provider's computer 186, a network42, one or more databases 40, and a server 188. The bio-medical unit 10includes a power harvesting module 46, a processing module 50, memory52, and a MMW transceiver 138. The memory 52 is storing URL data for thepatient 190. Note that the bio-medical unit 10 may be implanted in thepatient, on the patient's body, or on the patient's person (e.g., in amedical tag, a key chain, etc.).

The URL data 190 includes one or more URLs 192 that identify locationsof the patient's medical records. For example, one URL may be for thepatient's prescription records, another may be for hospitalizations,another for general office visits, etc. In this regard, the bio-medicalunit 10 is an index to easily access the patient's medical history.

For a service provider to access the patient's medical records, or aportion thereof, the patient's cell phone retrieves 200 the URL(s) 192from the bio-medical unit 10. The cell phone 200 generates a request toaccess the patient's information, where the request includes the URL(s)192, the service provider's ID, the patient's ID, and a data request.The request is provided, via the WAN device 34 and the network 42, tothe server 188.

The server 188 processes 198 the request. If the service provider isauthenticated and the request is valid, the server issues a dataretrieval message to the one or more databases 40 identified by theURL(s) 192. The addressed database(s) 40 retrieves the data and providesit via the network 42 and the WAN device 34 to the service provider'scomputer 186.

FIG. 23 is a diagram of another embodiment of a system that includes oneor more bio-medical units 10, the patient's cell phone 200, a WANcommunication device 34, a service provider's computer 186, a network42, one or more databases 40, and a server 188. The bio-medical unit 10includes a power harvesting module 46, a processing module 50, memory52, and a MMW transceiver 138. The memory 52 is storing URL data for thepatient. Note that the bio-medical unit 10 may be implanted in thepatient, on the patient's body, or on the patient's person (e.g., in amedical tag, a key chain, etc.).

The URL data includes one or more URLs that identify locations of thepatient's medical records. For example, one URL may be for the patient'sprescription records, another may be for hospitalizations, another forgeneral office visits, etc. In this regard, the bio-medical unit is anindex to easily access the patient's medical history.

To update the URL(s) in the bio-medical unit 10, the server 188determines when an update is needed 212. When an update is needed, theserver 188 generates an update message that includes the identity of thepatient's cell phone 200, the updated URL data 208, and the identity ofthe bio-medical unit 10. The server 188 provides the update message tothe patient's cell phone 200 via the network 42 and a base station 202.The patient's cell phone 200 processes the update message and, whenvalidated, provides the updated URL data 208 to the bio-medical unit 10for storage in memory 52 as stored updated patient URL(s) 206.

FIG. 24 is a schematic block diagram of an embodiment of networkedbio-medical units 10 that communicate with each other, perform sensingfunctions to produce sensed data 218-232, process the sensed data toproduce processed data, and transmit the processed data 216.

The bio-medical units 10 may be positioned in a body part to sense dataacross the body part and to transmit data to an external communicationdevice. The transmitted data may be further processed or aggregated fromsensed data.

The bio-medical units 10 may monitor various types of biologicalfunctions over a short term or a long term to produce the sensed data218-232. Note that the sensed data 218-232 may include blood flow rate,blood pressure, temperature, air flow, blood oxygen level, density,white cell count, red cell count, position information, etc.

The bio-medical unit 10 establishes communications with one or moreother bio-medical units 10 to facilitate the communication of senseddata 218-232 and processed data 216. The communication may include EMsignals, MMW signals, optical signals, sound signals, and/or RF signals.

The bio-medical unit 10 may determine position information based on thesensed data 218-232 and include the position information in thecommunication. The bio-medical unit 10 may also determine a mode ofoperation based on one or more of a command, a list, a predetermination,sensed data, and/or processed data. For example, a bio-medical unit 10at the center of the body part may be in a mode to sense temperature anda bio-medical unit 10 at the outside edge of the body part may senseblood flow.

The bio-medical unit 10 may receive processed data 218-232 from anotherbio-medical unit and re-send the same processed data 218-232 to yetanother bio-medical unit 10. The bio-medical unit 10 may produceprocessed data based on sensed data 218-232 from the bio-medical unit 10and/or received processed data from another bio-medical unit 10.

FIG. 25 is a flowchart illustrating the processing of networkedbio-medical unit data where the bio-medical unit determines the sensemode based on one or more of a predetermination, a stored mode indicatorin memory, a command, and/or a dynamic sensed data condition. The methodbegins at step 234 where the bio-medical unit 10 determines the mode.

The method branches to step 240 when the bio-medical unit 10 determinesthat the mode is process and sense. The method continues to step 236when the bio-medical unit 10 determines that the mode is sense only.

At step 236, the bio-medical unit 10 gathers data from one or more ofthe functional modules 54 to produce sensed data. The bio-medical unit10 may transmit the sensed data 238 to another bio-medical unit 10and/or an external communication device in accordance with the sensemode. For example, the bio-medical unit 10 may transmit the sensed dataat a specific time, to a specific bio-medical unit 10, to a specificexternal communication device, after a certain time period, when thedata is sensed, and/or when the sensed data compares favorably to athreshold (e.g., a temperature trip point).

The method continues at step 240 where the bio-medical unit 10determines whether it has received data from another unit 10. If not,the method continues to step 250, where the bio-medical unit 10transmits its sensed data to another bio-medical unit 10 and/or anexternal communication device in accordance with the sense mode.

When the bio-medical unit 10 has received data from another unit, themethod continues at step 242, where the bio-medical unit 10 determines adata function to perform based on one or more of the content of thereceived data, the sensed data, a command, and/or a predetermination.The data function may one or more of initialization, comparing,compiling, and/or performing a data analysis algorithm.

The method continues at step 244, where the bio-medical unit 10 gathersdata from the functional modules 54, and/or the received data from oneor more other bio-medical units 10. The method continues at step 246,where the bio-medical unit 10 processes the data in accordance with afunction to produce processed data. In addition to the example providedabove, the function may also include the functional assignment of thebio-medical unit 10 as determined by a predetermination, a command,sensed data, and/or processed data (e.g., measure blood pressure fromthe plurality of bio-medical units and summarize the high, low, andaverage).

The method continues at step 248, where the bio-medical unit 10transmits the processed data to another bio-medical unit 10 and/or to anexternal communication device in accordance with the sense mode. Forexample, the bio-medical unit 10 may transmit the sensed data at aspecific time, to a specific bio-medical unit 10, to a specific externalcommunication device, after a certain time period, when the data issensed, and/or when the sensed data compares favorably to a threshold(e.g., a temperature trip point). Note that the communication protocolmay be the same or different between bio-medical units 10 and/or betweenthe bio-medical unit 10 and the external communication device.

FIG. 26 is a diagram of an embodiment of a physical therapy (PT) systemthat includes bio-medical units (BMU) 10 and an electromagnetic (EM)signal generating unit 225. Each of the bio-medical units 10 includes apower harvesting module, a wireless communication module, a processingmodule, and a functional module as shown in one or more preceding and/orsubsequent figures. The EM signal generating unit 225 includes at leastone signal generating module 227 and a plurality of near fieldcommunication (NFC) modules 231. An NFC module 231 may include a poweramplifier (PA) and at least one coil.

The EM signal generating unit 225 encircles, partially encircles,overlays, and/or is otherwise proximally located to a body object 229(e.g., knee, elbow, foot, ankle, calf, thigh, core, shoulder, etc.). Forinstance, the EM signal generating unit 225 may include a wearablehousing that fits over the body object (e.g., a sleeve, a knee brace, anadjustable cuff, etc.) or may be a separate piece of equipment that thebody object is place in or near to. In addition to supporting thecomponents of the electromagnetic signal generating unit 225, thewearable housing and/or other piece of equipment may support one or morebio-medical units 10 further facilitate physical therapy of the bodyobject 229.

In an example of operation, when the EM signal generating unit 225 isenabled, it provides an electromagnetic (EM) signal to the bio-medicalunits (BMU) 10, which are associated with the body part (e.g., on theskin, implanted under the skin, implanted in a muscle, embedded in anartificial body part, embedded in sutures, in the wearable housing,etc.). In particular, the signal generating module 227 (e.g., a phaselocked loop, a crystal oscillator, a clock circuit, a digital frequencysynthesizer, etc.) generates one or more signals (e.g., oscillation,clock signal, etc.). As an example, the signal generating module 227generates a sinusoidal signal having a selected frequency and amplitude.As another example, the signal generating module 227 generates asinusoidal signal having a varying frequency and/or varying amplitude.As yet another example, the signal generating module 227 generatessinusoidal signal that is gated on and off.

One or of more of the NFC modules receives the signal and converts itinto a component of the electromagnetic (EM) signal. For instance,several NFC modules convert the signal into EM signal components havingdifferent gating on/off times, different frequencies, differentamplitudes, etc., such that, in air, the EM signal components combine toform a varying EM signal.

The power harvesting module of a BMU 10 generates a supply voltage fromthe electromagnetic signal as previously discussed. The supply voltageis used to power the wireless communication module, the processingmodule, and the functional module. When powered, the wirelesscommunication module converts a received wireless communication into aphysical therapy command. The wireless communication may be receivedfrom a wireless communication device (e.g., a cell phone, a computer,the EM signal generating unit 225, etc.), which is controlling thephysical therapy on the body part.

The processing module interprets the physical therapy command todetermine a physical therapy function. For example, the physical therapyfunction may be an electronic stimulation function, a monitoringfunction, and/or an electromyography function. The electric stimulationmay be used to promote healing, reduce pain, promote blood flow, reduceswelling, etc., which may be administered by a BMU of FIGS. 45, 46,and/or 55. The monitoring function may include one or more of monitoringcorrect form of a physical therapy movement, monitoring programcompliance (e.g., track sets, reps of movements, daily performance ofmovements, duration of PT session, duration of each movement, etc.),monitoring effort level (e.g., monitor muscle contraction, monitormuscle expansion, heart rate, blood-oxygen level, monitor electricalpatterns of muscle neurotransmitters, etc.), and monitoring pain level(e.g., monitor electrical patterns of pain neurotransmitters, etc.).

The functional module of the bio-medical unit 10 performs the physicaltherapy function. When the physical therapy function is a monitoringfunction, the functional module generates physical therapy data inresponse to performing the physical therapy function. For example, ifthe physical therapy function is to monitor a physical therapy movement,the functional module senses movement (e.g., with respect to a fixedreference point) of the body object such that the actual movement can becompared to a desired movement. If the actual movement is not asdesired, feedback and/or corrective measures can be provided to thephysical therapy patient. For example, a message may be sent to thepatient's cell phone indicating the improver form and a method forcorrecting it. As another example, an electrical stimulus may beactivated within the BMU to provide feedback regarding impropermovement, to enhance movement, to reduce pain, etc.

When physical therapy data is generated, the processing module generatesa physical therapy response based on physical therapy data. Thecommunication module converts the physical therapy response into atransmit wireless communication that is transmitted to the wirelesscommunication device and/or to the EM signal generating unit 225.

FIG. 27 is a diagram of an embodiment of an electromagnetic (EM) signalgenerating unit 225 that includes at least one signal generating unit227, at least one near field communication (NFC) module, a processingmodule 231, and at least one communication module 233. In an example,the EM signal generating unit 225 includes a plurality of signalgenerating units 227, a corresponding number of NFC modules, and twocommunication units 233 and 237: where one communication unit 233communicates with bio-medical units (BMU) 10 and the other communicationunit 237 communicates with a wireless communication device 235 (e.g., acell phone, a computer, medical equipment, etc.).

In an example of operation, the processing module 231 enables the signalgenerating units 227 in a pattern such that each pairing of a signalgenerating unit and an NFC module generates a component of a varyingelectromagnetic field. For instance, each pairing may be enabled at adifferent frequency, at a different power level, for a differentduration, etc., at the same frequency, at the same power level, for thesame duration, etc. and/or a combination thereof. In this manner, theprocessing module 231 can enable various electromagnetic signals topower the BMUs 10.

In addition, the processing module executes a physical therapy programto produce one or more physical therapy commands. The physical therapyprogram may be stored within memory of the EM signal generating unit 225or the processing module may receive, via the communication unit 237,the physical therapy program from the wireless communication device 235.In either case, the physical therapy program contains a set ofinstructions to monitor a body object's movements, efforts, and/or painlevels through a series of physical therapy exercises and/or treatments;to track compliance with performance of the physical therapy exercisesand/or treatments; to provide electric stimulation to facilitate thephysical therapy treatments; and/or to facilitate an electromyography.

For each physical therapy (PT) function to be performed by one or morebio-medical units (BMU) 10, the processing module 231 transmits, via thecommunication unit 231 or at least one of the NFC modules, the PTfunction to the BMU(s) 10. One or more of the BMUs 10 provides a PTresponse via the communication unit 231 or at least one of the NFCmodules, which is, in turn, received by the processing module. Theprocessing module 231 gathers the responses from the BMUs and processesthem to produce PT data (e.g., program compliance data, monitoring data,effort level data, pain level data, etc.).

FIG. 28 is a diagram of another embodiment of a bio-medical unit (BMU)10 that includes a power harvesting module 46, a communication module48, a processing module 50, and a functional module 255. The powerharvesting module 46 generates a supply voltage 56 from anelectromagnetic signal 241 it receives from the EM signal generatingunit 225. The supply voltage 56 powers the other modules of the BMU 10.

In an example of operation, the wireless communication module 48converts a received wireless communication 243 into a physical therapycommand 245. The processing module 50 interprets the physical therapycommand 245 to determine a physical therapy function 247. The functionalmodule 255 (e.g., any one of modules 98-114 of FIGS. 16, 45, 46)performs the physical therapy function and to generate physical therapydata 249 when the physical therapy function is a monitoring function.

The processing module 50 generates a physical therapy response 251 basedon physical therapy data 249. The wireless communication module 48converts the physical therapy response 251 into a transmit wirelesscommunication 245, which is transmitted to a communication unit 233 ofthe EM signal generating unit 225 and/or to the wireless communicationdevice 237.

FIG. 29 is a diagram of an embodiment of an integrated circuit (IC) 255that includes a die 253 and an IC package housing. The die 253 supportsa bio-medical unit 10 that includes a power harvesting module 46, acommunication module 48, a processing module 50, and at least onefunctional module 255. The IC package houses the die 253 and includes aclothing fabric adhering mechanism 257, which allows the IC 255 to beadhered to a clothing fabric. Note that the IC 255 may further includean encapsulant for encapsulating the IC package such that the IC isessentially hermetically sealed. Further note that the size of the IC255 may be less than 1 millimeter by 1 millimeter.

The fabric adhering mechanism 257 may be implemented in a variety ofways. For example, the fabric adhering mechanism 257 may include one ormore eyelets for facilitating sewing the IC into clothing fabric. Asanother example, the fabric adhering mechanism 257 may include one ormore hooks for facilitating sewing the IC into clothing fabric. As yetanother example, the fabric adhering mechanism 257 may include one ormore notches for facilitating sewing the IC into clothing fabric. As afurther example, the fabric adhering mechanism 257 may include a fabricadhesive for facilitating gluing the IC into clothing fabric.

FIG. 30 is a diagram of an embodiment of an article of clothing 275 thatincludes a clothing fabric 271 (e.g., cotton, dry-fit material,polyester, etc.) and a plurality of bio-medical units (BMU) 275integrated therein (e.g., in the seams of the article of clothing and/orin small pouches 267 of the article of clothing). Each of the BMUs 10includes a power harvesting module 46, a communication module 48, aprocessing module 50, and at least one functional module 255. The BMUs10 communicate with a wireless communication 235 via their respectivecommunication units 28.

In an example of operation, a power harvesting module 46 of a BMU 10converts at least one of body heat, body motion, an electromagneticsignal, light, and radio frequency (RF) signals into a supply voltagethat powers the other modules of the BMU 10. The power harvesting module46 may be implemented in a variety of ways, including combinationsthereof. For example, the power harvesting module 46 includes anelectromagnetic signal to voltage conversion module, which may includean array of inductors and/or an array of Hall-effect devices aspreviously discussed with reference to one or more of FIGS. 11-15. Asanother example, the power harvesting module 46 includes an RF signal tovoltage conversion module for converting a continuous wave (CW) signal261 and/or an RF signal 263 into the supply voltage. As yet anotherexample, the power harvesting module 46 includes a motion to voltageconversion module (e.g., piezoelectric devices as shown in one or moreof FIGS. 11-15). As a further example, the power harvesting module 46includes a light to voltage conversion module. As a still furtherexample, the power harvesting module 46 includes a heat to voltageconversion module.

When powered, the communication module 48 is operable to convert aninbound wireless signal 263 into an inbound symbol stream. Theprocessing module 50 converts the inbound symbol stream into abio-medical function, which may be an image capture function, a movementcapture function, a sound capture function, a topical treatmentfunction, and/or an electronic stimulation function. The functionalmodule 255 performs the bio-medical function and, when the bio-medicalfunction is a monitoring function, generates a bio-medical response.

The processing module converts the bio-medical response into theoutbound symbol stream. The communication module 48 converts theoutbound symbol stream into an outbound wireless signal 265 that istransmitted to the wireless communication device 235.

FIGS. 31 a and 31 b are logic diagrams of an embodiment of a method forcommunication with an article of clothing that includes a plurality ofbio-medical units. The method of FIG. 31 a may be executed by a wirelesscommunication device that includes a processing module and memory thatstores the bio-medical application in a computer readable format and themethod of FIG. 31 b may be executed by one or more bio-medical unitsintegrated into clothing fabric.

The method begins at step 291 where the wireless communication devicetransmits a continuous wave (CW) signal for predetermined period of time(e.g., a few milliseconds to 10s of seconds). At step 297, the powerharvesting module of a bio-medical unit converts the CW signal into asupply voltage, which powers the other modules of the BMU.

The method continues at step 293 where, after expiration of thepredetermined period of time, the wireless communication devicetransmits a radio frequency (RF) signal, which includes one or morebio-medical commands for one or more BMUs. The RF signal may furtherinclude a command to convert the RF signal into the supply voltage. Atstep 299, the communication unit of the bio-medical unit converts the RFsignal into an inbound symbol stream. At step 301, a processing moduleof the bio-medical unit converts the inbound symbol stream into abio-medical command. At step 303, a functional module of the bio-medicalunit performs the bio-medical command and, when commanded, generates abio-medical response. At step 305, the processing module converts thebio-medical response into an outbound symbol stream. At step 307, thecommunication unit converts the outbound symbol stream into an outboundRF response signal.

The method continues at step 295, where the wireless communicationdevice receives the RF response signal. In one instance, the RF responsesignal includes a request for re-transmission of the CW signal (e.g.,the BMU did not have sufficient power to complete the bio-medicalfunction).

The wireless communication device may also further function to, aftersending the RF signal, resume transmitting the CW signal. The wirelesscommunication device then indicates a time window for when thebio-medical is to transmit the RF response signal. The wirelesscommunication device stops transmitting the CW signal during the timewindow.

FIG. 32 is a diagram of an embodiment of a system 301 for medicationcontrol that includes bio-medical units (BMU) 10, a wireless powersource 305, and a wireless communication module 303. Each of the BMUs 10includes a power harvesting module 46, a communication module 48, aprocessing module 50, and at least one medication control module 307.Note that a wireless communication device (e.g., 235) may include thewireless communication module and the wireless power source.

In an example of operation, the wireless power source 305 (e.g., an MRIunit, a portable MRI unit, an EM signal generating unit 225, or anotherdevice that generates a varying EM signal) generates an electromagneticsignal 241. The power harvesting module of a BMU converts theelectromagnetic signal into a supply voltage, which powers the othermodules of the BMU.

With the BMU 10 powered, the wireless communication module transmits aninbound wireless signal to the bio-medical unit, where the inboundwireless signal 309 has, embedded therein, a medication controlfunction. The communication module 48 of the BMU converts the inboundwireless signal 309 into an inbound symbol stream 311. The processingmodule 50 converts the inbound symbol stream 311 into a medicationcontrol function 313 (e.g., sample a body component for presence and/orconcentration of a medication, administer a medication, etc.).

The medication control module 307 (e.g., as shown in one or more ofFIGS. 59-62) performs the medication control function 313 and generatesa medication response 315 as a result of performing the medicationcontrol function. The processing module 50 converts the medicationresponse 315 into the outbound symbol stream 317. The communicationmodule 48 converts the outbound symbol stream 317 into an outboundwireless signal 319, which is transmitted to the wireless communicationmodule 303.

In a more specific example, the medication control function includes aninstruction to sample a body component (e.g., blood, blood component,bodily fluid, air intake, exhale, human waste, etc.) for the presence(e.g., to determine if the person is taking the drug) and/orconcentration of a medication (e.g., to determine how much of the drugis being taken). In this example, the medication control module includesa probe mechanism, a testing module, and a cleaning mechanism. The probemechanism (e.g., needle and pipette of FIG. 62) samples the bodycomponent. The testing module (e.g., MEMS sample analyzer of FIG. 62)tests the body component for the presence and/or concentration of themedication to produce the medication response. The cleaning mechanism(e.g., wave based MEMS cleaner of FIG. 62) cleans the probe mechanismand the testing module after testing the body component.

The wireless communication module 303 receives the medication responseregarding the testing of the body component and interprets it todetermine whether the medication is under-utilized, over-utilized, orappropriately utilized. When the medication is over-utilized, thewireless communication module determines an over-utilized response basedon level of over-utilization. For example, if the medication is slightlyover-used, the response may be to send a text message to the patientand/or the patient's doctor. As another example, if the medication wasused to an overdose level, then the response may be to contact emergencymedical services. When the medication is under-utilized, the wirelesscommunication module determines an under-utilized response based onlevel of under-utilization. For example, if the medication is slightlyunder-used, the response may be to send a text message to the patientand/or the patient's doctor. As another example, if the medication isnot being used, the response may to test the patient's vital signs(e.g., if at undesired levels, contact emergency medical services), tosend a text message to the patient and/or the patient's doctor, or otherresponse.

In another more specific example, the medication control functionincludes an instruction to administer a medication. In this example, themedication control module includes a medication canister and a MEMScontrolled release module as shown in one or more of FIGS. 59-61. Themedication canister contains the medication and the microelectromechanical system (MEMS) controlled release module releases themedication in a controlled manner.

In another example of the operation, the bio-medical units 10 includeBMUs for a specific task regarding medication control. For example, afirst bio-medical unit monitors the presence and/or the concentration ofa first medication in a body component; a second bio-medical unitmonitors the presence and/or the concentration of a second medication ina body component (e.g., the same or different as checked for the firstmedication); a third bio-medical unit monitor a first type of bodilyreaction to medication (e.g., change in body temperature, change inwhite and/or red blood cell count, etc.); and a fourth bio-medical unitmonitors a second type of bodily reaction to medication. In this manner,when a patient is taking multiple medications, the bodies reactions canbe monitored as well as when, how often, and how much of the medicationsthe patient is taking.

Continuing with this example, the wireless communication module receivesthe medication response to include data regarding the at least one ofpresence and concentration of the first medication, data regarding theat least one of presence and concentration of the second medication,data regarding the first type of bodily reaction to medication, and dataregarding the second type of bodily reaction to medication. The wirelesscommunication module 303 interprets the medication response to determinewhether an undesired medication reaction is occurring. When theundesired medication reaction is occurring, the wireless communicationmodule determines a medication alert response (e.g., notify patient,notify patient's doctor, record in patient's records, contact emergencymedical services, etc.) regarding the undesired medication reactionbased on level of the undesired medication reaction.

FIGS. 33A and 33B are logic diagrams of an embodiment of a method forcontrolling and/or monitoring medication administration. The method ofFIG. 33A may be executed by a wireless communication device thatincludes a processing module and memory that stores the bio-medicalapplication in a computer readable format and the method of FIG. 33B maybe executed by one or more bio-medical units integrated into clothingfabric. Note that the wireless communication device may generate anelectromagnetic signal that wirelessly powers one or more of thebio-medical units.

The method begins at step 331 where the wireless communication devicegenerates a medication control function. The method continues at step333 where the wireless communication device converts the medicationcontrol function into a wireless control signal. The method continues atstep 335 where the wireless communication device transmits the wirelesscontrol signal to one or more bio-medical units.

At step 341, the bio-medical unit recaptures the medication controlfunction from the wireless control signal. At step 343, the bio-medicalunit performs the medication control function. At step 345, thebio-medical unit generates the medication response in response toperforming the medication control function. At step 347, the bio-medicalunit converts the medication response into a wireless response signal.

The method continues at step 337 where the wireless communication devicereceives the wireless response signal. The method continues at step 339where the wireless communication device recaptures the medicationresponse from the wireless response signal.

As a specific example, when the medication control function includes aninstruction to sample a body component for the presence and/orconcentration of a medication, the wireless communication devicerecaptures, as the medication response, the presence and/or theconcentration of the medication in a body component. The wirelesscommunication device then interprets the medication response todetermine whether the medication is under-utilized, over-utilized, orappropriately utilized. When the medication is over-utilized, thewireless communication device determines an over-utilized response basedon level of over-utilization. When the medication is under-utilized, thewireless communication device determines an under-utilized responsebased on level of under-utilization.

As another specific example, the wireless communication device receivesa plurality of wireless response signals and recaptures a plurality ofmedication responses from the wireless response signals. In particular,a first medication response corresponds to the presence and/or theconcentration of a first medication in the body component; a secondmedication response corresponds to the presence and/or the concentrationof a second medication in the body component; a third medicationresponse corresponds to a first type of bodily reaction to medication;and a fourth medication response corresponds to a second type of bodilyreaction to medication. The wireless communication device theninterprets the medication responses to determine whether an undesiredmedication reaction is occurring. When the undesired medication reactionis occurring, the wireless communication device determines a medicationalert response regarding the undesired medication reaction based onlevel of the undesired medication reaction.

FIG. 34 is a mechanical diagram of an embodiment of an embeddedbio-medical unit 10 in an artificial body part (e.g., a metal screw orplate), which includes a cavity as the bio-medical mounting mechanism.As shown, the bio-medical unit 10 is mounted within, or at leastpartially within, the cavity and the structure of the artificial bodypart provides the antenna and/or coil for the bio-medical unit 10. Notethat a plurality of embedded bio-medical units 10 may be utilized fordiagnostics and/or treatment of health issues. For example, theplurality of bio-medical units 10 may be embedded in a plurality ofmetal screws that are inserted in a bone to repair a break. Thebio-medical units 10 may monitor the position of the bone to detect anyundesired stress, cracks, breaks, and/or any other potential issues.

FIG. 35 is a mechanical diagram of another embodiment of an embeddedbio-medical unit 10 in an artificial body part (e.g., a metal screw orplate), which includes multiple cavities as the bio-medical mountingmechanism. As shown, the bio-medical unit 10 is mounted within, or atleast partially within, one cavity and the antenna and/or coil ismounted within, or at least partially within, another cavity. Note thata plurality of embedded bio-medical units 10 may be utilized fordiagnostics and/or treatment of health issues. For example, theplurality of bio-medical units 10 may be embedded in a plurality ofnon-metal plates that are attached to a bone to repair a break. Thebio-medical units 10 may monitor the position of the bone to detect anyundesired stress, cracks, breaks, and/or any other potential issues.

FIG. 36 is a mechanical diagram of an embedded bio-medical unit 10 in anartificial body part (e.g., a metal screw or plate), which includes acavity as the bio-medical mounting mechanism. As shown, the bio-medicalunit 10 is mounted within, or at least partially within, the cavity andthe antenna and/or coil for the bio-medical unit 10 is contained, orfunctions as, the threads of a screw. Note that a plurality of embeddedbio-medical units 10 may be utilized for diagnostics and/or treatment ofhealth issues. For example, the plurality of bio-medical units 10 may beembedded in a plurality of non-metal screws that are attached to a boneto repair a break. The bio-medical units 10 may monitor the position ofthe bone to detect any undesired stress, cracks, breaks, and/or anyother potential issues.

FIG. 37 is a mechanical diagram of another embodiment of an embeddedbio-medical unit 10 in a solid object (e.g., a non-metal screw orplate). At least one cavity is provided in the solid object to containthe bio-medical unit 10 and an antenna. A duct extends from the outsidesurface of the solid object to the at least one cavity containing thebio-medical unit 10 to provide a sampling and/or treatment cavity 242.The bio-medical device functional module 54 may gather data and/ordeliver a treatment (e.g., drugs) via the duct by coupling thebio-medical unit to the body. Note that a plurality of embeddedbio-medical units 10 may be utilized for diagnostics and/or treatment ofhealth issues. For example, the plurality of bio-medical units 10 may beembedded in a plurality of non-metal screws that are attached to a boneto repair a break. The bio-medical units 10 may administer a drugtreatment from time to time (e.g., bone cancer drugs) via the samplingand/or treatment cavity 242.

FIG. 38 is a schematic block diagram of an embodiment of a parentbio-medical unit (on the left) communicating with an external unit tocoordinates the functions of one or more children bio-medical units 10(on the right). The parent unit includes a communication module 48 forexternal communications, a communication module 48 for communicationwith the children units, the processing module 50, the memory 52, andthe power harvesting module 46. Note that the parent unit may beimplemented one or more chips and may in the body or one the body.

Each of the child units includes a communication module 48 forcommunication with the parent unit and/or other children units, a MEMSrobotics 244, and the power harvesting module 46. The MEMS robotics 244may include one or more of a MEMS technology saw, drill, spreader,needle, injection system, and actuator. The communication module 48 maysupport RF and/or MMW inbound and/or outbound signals 60 to the parentunit such that the parent unit may command the child units in accordancewith external communications commands.

In an example of operation, the patent bio-medical unit receives acommunication from the external source, where the communicationindicates a particular function the child units are to perform. Theparent unit processes the communication and relays relative portions tothe child units in accordance with a control mode. Each of the childunits receives their respective commands and performs the correspondingfunctions to achieve the desired function.

FIG. 39 is a schematic block diagram of another embodiment of aplurality of task coordinated bio-medical units 10 including a parentbio-medical unit 10 (on the left) and one or more children bio-medicalunits 10 (on the right). The parent unit may be implemented one or morechips and may in the body or one the body. The parent unit may harvestpower in conjunction with the power booster 84.

The parent unit includes the communication module 48 for externalcommunications, the communication module 48 for communication with thechildren units, the processing module 50, the memory 52, a MEMSelectrostatic motor 248, and the power harvesting module 46. The childunit includes the communication module 48 for communication with theparent unit and/or other children units, a MEMS electrostatic motor 248,the MEMS robotics 244, and the power harvesting module 46. Note that thechild unit has fewer components as compared to the parent unit and maybe smaller facilitating more applications where smaller bio-medicalunits 10 enhances their effectiveness.

The MEMS robotics 244 may include one or more of a MEMS technology saw,drill, spreader, needle, injection system, and actuator. The MEMSelectrostatic motor 248 may provide mechanical power for the MEMSrobotics 244 and/or may provide movement propulsion for the child unitsuch that the child unit may be positioned to optimize effectiveness.The child units may operate in unison to affect a common task. Forexample, the plurality of child units may operate in unison to sawthrough a tissue area.

The child unit communication module 48 may support RF and/or MMW inboundand/or outbound signals 60 to the parent unit such that the parent unitmay command the children units in accordance with externalcommunications commands.

The child unit may determine a control mode and operate in accordancewith the control mode. The child unit determines the control mode basedon one or more of a command from a parent bio-medical unit, externalcommunications, a preprogrammed list, and/or in response to sensor data.Note that the control mode may include autonomous, parent (bio-medicalunit), server, and/or peer as previously discussed.

FIG. 40 is a schematic block diagram of an embodiment of a bio-medicalunit 10 based imaging system that includes the bio-medical unit 10, thecommunication device 24, a database 254, and an in vivo image unit 252.The bio-medical unit 10 may perform scans and provide the in vivo imageunit 252 with processed image data for diagnostic visualization.

The bio-medical unit 10 includes a MEMS image sensor 256, thecommunication module 48 for external communications with thecommunication device, the processing module 50, the memory 52, the MEMSelectrostatic motor 248, and the power harvesting module 46. In anembodiment the bio-medical unit 10 and communication device 24communicate directly. In another embodiment, the bio-medical unit 10 andcommunication device 24 communicate through one or more intermediatenetworks (e.g., wireline, wireless, cellular, local area wireless,Bluetooth, etc.). The MEMS image sensor 256 may include one or moresensors scan types for optical signals, MMW signals, RF signals, EMsignals, and/or sound signals.

The in vivo unit 252 may send a command to the bio-medical unit 10 viathe communication device 24 to request scan data. The request mayinclude the scan type. The in vivo unit 252 may receive the processedimage data from the bio-medical unit 10, compare it to data in thedatabase 254, process the data further, and provide image visualization.

FIG. 41 is a schematic block diagram of an embodiment of a communicationand diagnostic bio-medical unit 10 pair where the pair utilize anoptical communication medium between them to analyze material betweenthem (e.g., tissue, blood flow, air flow, etc,) and to carry messages(e.g., status, commands, records, test results, scan data, processedscan data, etc.).

The bio-medical unit 10 includes a MEMS light source 256, a MEMS imagesensor 258, the communication module 48 (e.g., for externalcommunications with the communication device 24), the processing module50, the memory 52, the MEMS electrostatic motor 248 (e.g., forpropulsion and/or tasks), and the power harvesting module 46. Thebio-medical unit 10 may also include the MEMS light source 256 tofacilitate the performance of light source tasks. The MEMS image sensor258 may be a camera, a light receiving diode, or infrared receiver. TheMEMS light source 256 may emit visible light, infrared light,ultraviolet light, and may be capable of varying or sweeping thefrequency across a wide band.

The processing module 50 may utilize the MEMS image sensor 258 and theMEMS light source 256 to communicate with the other bio-medical unit 10using pulse code modulation, pulse position modulation, or any othermodulation scheme suitable for light communications. The processingmodule 50 may multiplex messages utilizing frequency division,wavelength division, and/or time division multiplexing.

The bio-medical optical communications may facilitate communication withone or more other bio-medical units 10. In an embodiment, a stararchitecture is utilized where one bio-medical unit 10 at the center ofthe star communicates to a plurality of bio-medical units 10 around thecenter where each of the plurality of bio-medical units 10 onlycommunicate with the bio-medical unit 10 at the center of the star. Inan embodiment, a mesh architecture is utilized where each bio-medicalunit 10 communicates as many of the plurality of other bio-medical units10 as possible and where each of the plurality of bio-medical units 10may relay messages from one unit to another unit through the mesh.

The processing module 50 may utilize the MEMS image sensor 258 and theMEMS light source 256 of one bio-medical unit 10 to reflect lightsignals off of matter in the body to determine the composition andposition of the matter. In another embodiment, the processing module 50may utilize the MEMS light source 256 of one bio-medical unit 10 and theMEMS image sensor 258 of a second bio-medical unit 10 to pass lightsignals through matter in the body to determine the composition andposition of the matter. The processing module 50 may pulse the light onand off, sweep the light frequency, vary the amplitude and may use otherperturbations to determine the matter composition and location.

FIG. 42 is a schematic block diagram of an embodiment of a bio-medicalunit 10 based sounding system that includes the bio-medical unit 10, thecommunication device 24, the database 254, and a speaker 260. Thebio-medical unit 10 may perform scans and provide the speaker 260 withprocessed sounding data for diagnostic purposes via the communicationdevice 24.

The bio-medical unit 10 includes a MEMS microphone 262, thecommunication module 48 for external communications with thecommunication device 24, the processing module 50, the memory 52, theMEMS electrostatic motor 248, and the power harvesting module 46. In anembodiment the bio-medical unit 10 and communication device 24communicate directly. In another embodiment, the bio-medical unit 10 andcommunication device 24 communicate through one or more intermediatenetworks (e.g., wireline, wireless, cellular, local area wireless,Bluetooth, etc.) The MEMS microphone 262 may include one or more sensorsto detect audible sound signals, sub-sonic sound signals, and/orultrasonic sound signals.

The processing module 50 may produce the processed sounding data basedin part on the received sound signals and in part on data in thedatabase 254. The processing module 50 may retrieve data via thecommunication module 48 and communication device 24 link from thedatabase 254 to assist in the processing of the signals (e.g., patternmatching, filter recommendations, sound field types). The processingmodule 50 may process the signals to detect objects, masses, air flow,liquid flow, tissue, distances, etc. The processing module 50 mayprovide the processed sounding data to the speaker 260 for audibleinterpretation. In another embodiment, the bio-medical unit 10 assistsan ultrasound imaging system by relaying ultrasonic sounds from the MEMSmicrophone 262 to the ultrasound imaging system instead of to thespeaker 260.

FIG. 43 is a schematic block diagram of another embodiment of abio-medical unit 10 communication and diagnostic pair where the pairutilize an audible communication medium between them to analyze materialbetween them (e.g., tissue, blood flow, air flow, etc,) and to carrymessages (e.g., status, commands, records, test results, scan data,processed scan data, etc.). The bio-medical unit 10 includes the MEMSmicrophone 262, a MEMS speaker 264, the communication module 48 (e.g.,for external communications with the communication device), theprocessing module 50, the memory 52, the MEMS electrostatic motor 248(e.g., for propulsion and/or tasks), and the power harvesting module 46.The bio-medical unit 10 may also include the MEMS speaker 264 tofacilitate performance of sound source tasks.

The MEMS microphone 262 and MEMS speaker 264 may utilize audible soundsignals, sub-sonic sound signals, and/or ultrasonic sound signals andmay be capable of varying or sweeping sound frequencies across a wideband. The processing module 50 may utilize the MEMS microphone 262 andMEMS speaker 264 to communicate with the other bio-medical unit 10 usingpulse code modulation, pulse position modulation, amplitude modulation,frequency modulation, or any other modulation scheme suitable for soundcommunications. The processing module 50 may multiplex messagesutilizing frequency division and/or time division multiplexing.

The bio-medical sound based communications may facilitate communicationwith one or more other bio-medical units 10. In an embodiment, a stararchitecture is utilized where one bio-medical unit 10 at the center ofthe star communicates to a plurality of bio-medical units 10 around thecenter where each of the plurality of bio-medical units 10 onlycommunicate with the bio-medical unit 10 at the center of the star. Inan embodiment, a mesh architecture is utilized where each bio-medicalunit 10 communicates as many of the plurality of other bio-medical units10 as possible and where each of the plurality of bio-medical units 10may relay messages from one unit to another unit through the mesh.

The processing module 50 may utilize the MEMS microphone 262 and MEMSspeaker 264 of one bio-medical unit 10 to reflect sound signals off ofmatter in the body to determine the composition and position of thematter. In another embodiment, the processing module 50 may utilize theMEMS microphone 262 of one bio-medical unit 10 and the MEMS speaker 264of a second bio-medical unit 10 to pass sound signals through matter inthe body to determine the composition and position of the matter. Theprocessing module 50 may pulse the sound on and off, sweep the soundfrequency, vary the amplitude and may use other perturbations todetermine the matter composition and location.

FIG. 44 is a schematic block diagram of an embodiment of a sound basedimaging system including a plurality of bio-medical units 10 utilizingshort range ultrasound signals in the 2-18 MHz range to facilitateimaging a body object 268. The bio-medical unit 10 includes at least oneultrasound transducer 266, the communication module 48 (e.g., forexternal communications with the communication device and forcommunications with other bio-medical units), the processing module 50,the memory 52, and the power harvesting module 46. The ultrasoundtransducer 266 may be implemented utilizing MEMS technology.

The processing module 50 controls the ultrasonic transducer 266 toproduce ultrasonic signals and receive resulting reflections from thebody object 268. The processing module 50 may coordinate with theprocessing module 50 of at least one other bio-medical unit 10 toproduce ultrasonic signal beams (e.g., constructive simultaneous phasedtransmissions directed in one direction) and receive resultingreflections from the body object. The processing module 50 may performthe coordination and/or the plurality of processing modules 50 mayperform the coordination. In embodiment, the plurality of processingmodules 50 receives coordination information via the communicationmodule 48 from at least one other bio-medical unit 10. In anotherembodiment, the plurality of processing modules 50 receives coordinationinformation via the communication module 48 from an externalcommunication device.

The processing module produces processed ultrasonic signals based on thereceived ultrasonic reflections from the body object 268. For example,the processed ultrasonic signals may represent a sonogram of the bodypart. The processing module 50 may send the processed ultrasonic signalsto the external communication device and/or to one or more of theplurality of bio-medical units 10.

FIG. 45 is a schematic block diagram of an embodiment of an electricstimulation system that includes one or more bio-medical units 10capable of delivering an electric stimulation current (i.e., anelectrotherapy signal). Each of the bio-medical unit 10 includes astep-up DC-DC converter 270, an inverter 272, a switch 274, a probe 278,a nanotechnology or MEMS actuator 276, the communication module 48(e.g., for external communications with the communication device and forcommunications with other bio-medical units), the processing module 50,the memory 52, and the power harvesting module 46.

In an example of operation, the processing module 50 receives a messagevia the communication 48 that causes the processing module 50 togenerate a high voltage stimuli command as the command message. The painmanagement functional module (e.g., the MEMS actuator 276, the switch274, and/or the probe 278) receives the high voltage stimuli commandand, in response thereto, establishes a common ground with anotherbio-medical unit (e.g., couple via a probe or other electrical means).The pain management functional module then produces a high voltage inaccordance with the high voltage stimuli command.

For instance, the step-up DC-DC converter 270 converts a lower DCvoltage 280 output of the power harvesting module 46 to a higher DCvoltage 282. The inverter transforms the higher DC voltage 282 to ahigher AC voltage 284. The switch 274, based on the command message,selects one of at least a ground potential, the higher DC voltage 282,or the higher AC voltage 284 to apply to the probe 278. The probe 278applies the selected voltage potential to an object adjacent to thebio-medical unit 10 (e.g., a body point such as an acupuncture point, anerve, a muscle, etc.) when the probe 278 is mechanically extendedbeyond the outer encasement of the bio-medical unit 10. For example, theprocessing module 50 may control the MEMS actuator 276 to move the probe278 into position via force 286 to deliver the selected voltagepotential or to retract the probe 278 when it is not in use. In anotherexample, the probe 278 is in contact with the body without mechanicalmovement. Note that the processing module 50 may control the MEMSactuator 276 to move the probe 278 into position to deliver a groundpotential voltage potential to simulate an acupuncture application.

In another example of operation, the power harvesting module converts anelectromagnetic signal into a supply voltage, which powers theprocessing module and the pain management functional module. Theprocessing module determines a body point for application of paintreatment and a pain treatment duration. For example, the processingmodule determines the body point to correspond to a ligament with in aperson's knee. In addition, the processing module determines the paintreatment duration to be 15 minutes. The processing module thatgenerates a control signal regarding the body point and the paintreatment duration and provides the control signal to the painmanagement functional module.

In one instance, the communication module 48 receives a communicationfrom an external communication device 24 regarding the pain treatment.For example, the communication module receives a wireless communicationsignal from an external communication device 24 and converts it into abaseband or near-baseband signal. The processing module converts thebaseband or near-baseband signal into a pain treatment command. From thepain treatment command, the processing module determines at least one ofthe body point and the treatment duration.

The pain management functional module receives the control signal and,in response thereto, generates an electrotherapy signal, which isdirected toward the body point. For example, the pain managementfunctional module includes an actuator module 276, a needle probe 278,and a high-voltage generator (e.g., 270 and 272, which will be describedin greater detail with reference to FIG. 24). In response to the controlsignal, the actuator module 276 applies a force 286 upon the needleprobe 278 such that the needle probe is positioned proximal to the bodypoint. When in that position, the high-voltage generator produces theelectrotherapy signal that is applied to the body point via the needleprobe 278. While not shown in FIG. 23, the bio-medical unit may furtherinclude a cleaning module that is operable to clean the needle probe.

In general, electro-therapy, as applied by the bio medical unit 10, maybe used for such medical treatment as deep brain stimulation fortreating neurological diseases, to speed up wound healing, to improvebone healing, to provide pain management, to improve joint range ofmotion, to treat neuromuscular dysfunction, to improve motor control, toretard muscle atrophy, to improve local blood flow, to improve tissuerepair by enhancing microcirculation and protein synthesis, to restoreintegrity of connective and dermal tissue, to function as apharmacological agent, improve continence, and/or to relax musclespasms.

FIG. 46 is a schematic diagram of an embodiment of a voltage conversioncircuit including a step-up DC-DC converter 270 and an inverter 272. Thestep-up DC-DC converter 270 includes an input inductor 288, a pair ofswitching transistors, a smoothing capacitor, and a control circuit 290.The inductor 288 may be implemented as one or more air core inductors288. The control circuit 290 operates the switching transistors tointeract with the inductor 288 and capacitor to provide the higher DCvoltage 282 potential at the output.

The inverter 272 includes a transformer 294, a pair of switchingtransistors, and a control circuit 292. The transformer 294 may beimplemented as a 1:1 air core transformer 294 (or other turn ratios)with three single turn coils on different layers with the output betweenthe input coil layers. The control circuit 292 operates the switchingtransistors to interact with the inductance of the transformer 294 toprovide an alternating current at the input of the transformer 294 toproduce the higher AC voltage 284 potential at the output.

FIG. 47 is a schematic block diagram of an embodiment of a communicationmodule 48 of a bio-medical unit coupled to one or more antennaassemblies 94. The communication module 48 includes a MMW transmitter132, a MMW receiver 136, and a local oscillator generator 298 (LOGEN)and is coupled to the processing module 50. While not shown in thepresent figure, the bio-medical unit includes at least one powerharvesting module that converts an electromagnetic signal into one ormore supply voltages. The one or more supply voltages power the othercomponents of the bio-medical unit. Note that the bio-medical unit andthe antenna assemblies 94 may be implemented on one or more integratedcircuit (IC) dies within a common housing.

The one or more antenna assemblies 94 may include a common transmit andreceive antenna; a separate transmit antenna and a separate receiveantenna; a common array of antennas; and/or an array of transmitantennas and an array of receive antennas. The one or more antennaassemblies 94 may further include a transmission line, an impedancematching circuit, and/or a transmit/receive switch, duplexer, and/orisolator. Each of the antennas of the one or more antenna assemblies 94may be a leaky antenna as shown in FIG. 48 (discussed below) and may beimplemented using MEMS and/or nano technology 296.

In an example of operation, the bi-medical unit is exposed to anelectromagnetic signal as previously discussed. The power harvestingmodule generates a supply voltage from the electromagnetic signal, wherethe supply voltage powers the communication module 48 and the processingmodule 50. When powered, the processing module may receive a commandregarding a bio-medical function via the communication module. Acommunication device external to the host body or another bio-medicalunit may initiate the command, which is received as an inbound (ordownstream) RF or MMW signal by the communication module.

In response to receiving the command, the processing module interpretsit to determine whether the bio-medical function includes a radiofrequency transmission (e.g., for cancer treatment, imaging, painblocking, etc.). When the bio-medical function includes a radiofrequency transmission, the processing module determines a desiredradiation pattern for the antenna assembly. For example, the desiredradiation pattern may have a primary lobe perpendicular to the surfaceof the antenna, a primary lobe at an angle from perpendicular to thesurface, beamformed, etc. Various radiation patterns are shown in FIGS.49 and 50.

Having determined the desired radiation pattern, the processing modulethen determines an operating frequency based on the desired radiationpattern. For example, the processing module may use a look up table todetermine the operating frequency for a particular desired radiationpattern, which are determined based on the properties of the antenna(s).Once the operating frequency is established, the antenna assembly willtransmit outbound RF and/or MMW signals and receive inbound RF and/orMMW signals in accordance with the desired radiation pattern.

As a more specific example, after establishing the operating frequency,the processing module generates a continuous wave treatment signal inaccordance with the bio-medical function (e.g., for pain blocking, forcancer treatment, etc.). In addition, the processing module generates atransmit local oscillation control signal in accordance with thebio-medical function.

The local oscillation generator 298 receives the transmit localoscillation control signal and generates, in accordance therewith, atransmit local oscillation. The transmitter section receives thecontinuous wave treatment signal (which may be a DC signal, a fixedfrequency AC signal with a constant or varying amplitude, or a varyingfrequency AC with a constant or varying amplitude) and the transmitlocal oscillation. The transmitter section mixes the continuous wavetreatment signal and the transmit local oscillation to produce a radiofrequency (RF) continuous wave (CW) signal and outputs it to the antennaassembly, which transmits the RF CW signal in accordance with theradiation pattern.

As another more specific example, after establishing the operatingfrequency, the processing module generates a pulse treatment signal inaccordance with the bio-medical function (e.g., for pain blocking, forcancer treatment, etc.). In addition, the processing module generates atransmit local oscillation control signal in accordance with thebio-medical function.

The local oscillation generator 298 receives the transmit localoscillation control signal and generates, in accordance therewith, atransmit local oscillation. The transmitter section receives the pulsetreatment signal (which may be a pulse train having a constant amplitudeand a constant frequency, a pulse train having a constant amplitude andvarying frequency, a pulse train having a varying amplitude and aconstant frequency) and the transmit local oscillation. The transmittersection mixes the pulse treatment signal and the transmit localoscillation to produce a radio frequency (RF) pulse signal and outputsit to the antenna assembly, which transmits the RF pulse signal inaccordance with the radiation pattern.

As another more specific example, the processing module determines thatthe bio-medical function includes a radio frequency transmission forgenerating an image of a body object. In this instance, the processingmodule determines a varying operating frequency such that the radiationpattern of the antenna assembly varies to produce a varying radiationpattern. In addition, the processing module generates a varying transmitlocal oscillation control signal, which it provides to the localoscillation generator.

The transmitter section generates outbound radio frequency (RF) and/orMMW signals that have varying frequencies and outputs them to theantenna assembly. With the frequencies of the outbound RF signals, theradiation pattern of the antenna assembly will vary. As such, aradar-sweeping pattern is generated.

The receiver section 136 receives a representation of the outbound RFsignal (e.g., reflection, refraction, and/or a determined absorption).The receive section converts the representation of the outbound RFsignal into an inbound symbol stream. The processing module generates aradar image of a body object based on the outbound RF signal and therepresentation of the outbound RF signal.

In addition to providing RF transmissions to support a bio-medicalfunction, the bio-medical unit may also communicate with an externalcommunication device and/or with another bio-medical unit within thehost body. For instance, the processing module determines a secondradiation pattern for communication with a communication device externalto the host body using a second operating frequency, wherein the antennaassembly has the second radiation pattern for the communication at thesecond operating frequency. Such communications may be concurrent withthe supporting of the bio-medical function or in a time divisionmultiplexed manner.

As another example of operation, or in furtherance of the precedingexample, the antenna assembly includes adjustable physicalcharacteristics such that the radiation pattern can be adjusted. Forinstance, an antenna of the antenna assembly includes a first conductivelayer and a second conductive layer. The second conductive layer issubstantially parallel to the first conductive layer and is separated bya distance from the first conductive layer. The second conductive layerincludes a plurality of substantially equally spaced non-conductiveareas corresponding to a particular range of frequencies to facilitatethe radiation pattern for the particular range of frequencies. Tovarying the radiation patterns, the distance between the first andsecond conductive layers may be varied, the geometry of thenon-conductive areas may be varied, and/or the spacing between thenon-conductive areas may be varied.

Continuing with this example, the processing module receives a commandregarding a bio-medical function via the communication module andinterprets it. When the bio-medical function includes a radio frequencytransmission, the processing module determines antenna parameters forthe antenna assembly (e.g., for desired radiation patterns, determinedistance between conductive layers, geometry of the non-conductiveareas, and/or spacing between the non-conductive layers). The processingmodule then generates an antenna control signal based on the antennaparameters, which it provides to the antenna assembly.

FIG. 48 is a schematic block diagram of an embodiment of a leaky antenna94 that includes a channel and/or waveguide having a first conductivelayer and a second conductive layer. The layers are separated by adistance (d), which may be fixed or variable. The second conductivelayer includes a series of openings (e.g., non-conductive areas) tofacilitate the radiation of an electromagnetic signal 300 that istraveling down the waveguide. The geometry and/or spacing between theopenings may be fixed or variable.

The leaky antenna pattern (e.g., direction) is a function of at leastthe size of the openings, the distance between openings, and thefrequency of operation. For example, the distance between openings isset to about one wavelength of the nominal center frequency ofoperation. With the physical dimensions static, the leaky antennapattern may be adjusted with changes to frequency of operation (e.g.,above and below the center frequency).

FIG. 49 is a diagram of an antenna pattern at a first frequency ofoperation where the antenna pattern 302 may be substantially in the 90°direction with respect to the length wise direction of the leaky antennawaveguide. In this example, the distance between the openings of theleaky antenna 94 is substantially the same as the length of thewavelength of the frequency of operation.

FIG. 50 is a diagram of an antenna pattern at a second frequency ofoperation where the antenna pattern 304 may be substantially off of the90° direction with respect to the length wise direction of the leakyantenna waveguide. In this example, the distance between the openings ofthe leaky antenna 94 is different than the length of the wavelength ofthe frequency of operation.

FIG. 51 is a schematic block diagram of an embodiment of a system ofsuture bio-medical units 344 where a plurality of bio-medical units 344are positioning along an incision 342 suture line to diagnose and treatthe healing process. The bio-medical units 344 may be attached to orembedded in the suture materials including staples, glue, tape, thread,wire, etc. The suture material may be metal or non-metal.

The bio-medical units 344 may communicate with each other and/or with acommunication device 24 to communicate status information and/orcommands and/or to coordinate performance of functions. For instance,the bio-medical unit 344 may perform diagnostics including monitoringtemperature, taking images, pinging the incision with ultrasound,pinging the incision with MMW radar to produce diagnostic information.The bio-medical unit 344 may produce diagnostic results based on thediagnostic information. The diagnostic results may include indicationsor probabilities of high temperature, infection, behind the expectedhealing schedule, and/or ahead of the expected healing schedule.

The bio-medical unit 344 may send the diagnostic results and/ordiagnostic information to other bio-medical units 10, 344 and/or to thecommunication device 24 for further processing or commands. Thebio-medical unit 344 may determine to treat the healing process. Thetreatments may include administering medication, applying lasertreatment, applying ultrasound treatment, grasping, sawing, drilling,and/or providing an electronic stimulus. The determination may be basedon one of more of a predetermination, a command, and/or an adaptivealgorithm (e.g., to heal the incision faster).

FIG. 52 is a mechanical diagram of another embodiment of an embeddedbio-medical unit 10 in a solid object (e.g., a metal suture). A cavityis provided in the solid object to contain the bio-medical unit 10. Thecommunication module 48 antenna port of the bio-medical unit 10 may becoupled to the solid object such that the solid object provides anantenna and/or coil function. The communication module 48 may utilizethe solid object as the antenna for MMW communication, RF communication,and/or EM signaling. The bio-medical unit 10 may communicate sensed dataproduced from the functional module 54. Note that a plurality ofembedded bio-medical units 10 may be utilized for diagnostics and/ortreatment of health issues. For example, the plurality of bio-medicalunits 10 may be embedded in a plurality of metal sutures that are toaffect the healing of an incision. The bio-medical units 10 may monitorthe healing process to detect any undesired issues.

FIG. 53 is a mechanical diagram of another embodiment of an embeddedbio-medical unit 10 in a solid object (e.g., a non-metal suture). Atleast one cavity is provided in the solid object to contain thebio-medical unit 10 and an antenna. The communication module 48 antennais contained in at least one solid object cavity such that the antennamay receive and send MMW communication, RF communication, and/or EMsignaling. The bio-medical unit 10 may communicate sensed data producedfrom the functional module. Note that a plurality of embeddedbio-medical units 10 may be utilized for diagnostics and/or treatment ofhealth issues. For example, the plurality of bio-medical units 10 may beembedded in a plurality of metal sutures that are to affect the healingof an incision. The bio-medical units 10 may monitor the healing processto detect any undesired issues.

FIG. 54 is a mechanical diagram of another embodiment of an embeddedbio-medical unit 10 in a solid object (e.g., a non-metal suture). Atleast one cavity is provided in the solid object to contain thebio-medical unit 10 and an antenna. A sampling and/or treatment cavity242 extends from the outside surface of the solid object to the at leastone cavity containing the bio-medical unit 10. The bio-medical device 10functional module 54 may gather data and/or deliver a treatment (e.g.,drugs) via the sampling and/or treatment cavity 242 by coupling thebio-medical unit 10 to the body.

The communication module 48 antenna is contained in at least one solidobject cavity such that the antenna may receive and send MMWcommunication, RF communication, and/or EM signaling. The bio-medicalunit 10 may communicate sensed data produced from the functional module54. Note that a plurality of embedded bio-medical units 10 may beutilized for diagnostics and/or treatment of health issues. For example,the plurality of bio-medical units 10 may be embedded in a plurality ofmetal sutures that are to affect the healing of an incision. Thebio-medical units 10 may monitor the healing process to detect anyundesired issues. The bio-medical units 10 may administer a drugtreatment from time to time (e.g., infection fighting drugs) in responseto the undesired issues. In another embodiment, the bio-medical unit 10may administer an electric potential to mediate pain.

FIG. 55 is a schematic block diagram of an embodiment of a pain blockingbio-medical unit 10 to provide an amplitude modulated (AM) signal 346 tofacilitate gate control of pain. The bio-medical unit 10 includes thecommunication module 48 (e.g., for external communications with thecommunication device and for communications with other bio-medicalunits), a MEMS propulsion 348, the processing module 50, the memory 52,the power harvesting module 46, a frequency adjust 350, an amplitudemodulation 352, a MMW oscillator 354, and a power amplifier 356 (PA).

The bio-medical unit 10 may communicate with other bio-medical units 10and/or with the communication device 24 to communicate statusinformation and/or commands. The bio-medical unit 10 may receive acommand from the communication device 24 to reposition, adjust the MMWfrequency, and transmit MMW signals to mediate pain. In anotherembodiment, the communication device 24 may send a command to aplurality of bio-medical units 10 to coordinate the formation of a beamto better pinpoint the pain mediation.

The processing module 50 may control the MEMS propulsion 348 toreposition the bio-medical unit 10. The processing module 50 maydetermine how to control the frequency adjust 350 and amplitudemodulation 352 to affect the pain based on a command, apredetermination, and/or an adaptive algorithm (e.g., that detects localpain). The processing module 50 controls the frequency adjust 350 andamplitude modulation 352 in accordance with the determination such thatthe MMW oscillator 354 fed PA 356 generates an amplitude modulatedsignal 346.

FIG. 56 is a schematic block diagram of an embodiment of a Doppler radarbio-medical unit to provide a distancing radar function to determine thelocation of a body object 268. The bio-medical unit 10 includes thecommunication module 48 (e.g., for external communications with thecommunication device and for communications with other bio-medicalunits), the MEMS propulsion 348, the processing module 50, the memory52, the power harvesting module 46, a MMW frequency adjust 358, a mixer362, a low noise amplifier 360 (LNA), and a power amplifier 356 (PA).The bio-medical unit 10 may communicate with other bio-medical units 10and/or with a communication device 24 to communicate status informationand/or commands.

The bio-medical unit 10 may send a transmitted MMW signal 364 to thebody object 268 and receive a reflected MMW signal 366 from the bodyobject. 268. Some of the transmitted MMW signal energy is absorbed,reflected in other directions, and/or transmitted to other directions.The bio-medical unit 10 forms a Doppler radar sequence by varying thefrequency of the transmitted MMW signal 364 over a series oftransmission steps. The bio-medical unit 10 may determine the distanceand location information based on the reflected MMW signal 366 inresponse to the Doppler radar.

The bio-medical unit 10 may receive a command from the communicationdevice 24 to reposition, adjust the MMW frequency, and transmit MMWsignals to perform the Doppler radar function. In another embodiment,the communication device 24 may send a command to a plurality ofbio-medical units 10 to coordinate the formation of a beam to betterpinpoint the body object. In yet another embodiment, the communicationdevice 24 may send a command to a plurality of bio-medical units 10 tocoordinate the Doppler radar function from two, three or morebio-medical units 10 to triangulate the body object location based onthe distance information.

The processing module 50 may control the MEMS propulsion 348 toreposition the bio-medical unit 10. The processing module 50 maydetermine how to control the MMW frequency adjust 358 to affect thedistance information detection based on a command, a predetermination,and/or an adaptive algorithm (e.g., that detects course distance rangesat first and fine tunes the accuracy over time). The processing module50 controls the MMW frequency adjust 358 in accordance with thedetermination such that the PA 356 generates the desired transmitted MMWsignal 364. The LNA 360 amplifies the reflected MMW signal 366 and themixer 362 down converts the signal such that the processing module 50receives and processes the signal.

FIG. 57 is a timing diagram of an embodiment of a Doppler radar sequencewhere a transmit (TX) series 368 of MMW transmissions for the transmitsequence of transmitted MMW signals 364 and a receive (RX) series of MMWreceptions for the receive sequence of reflected MMW signals 366. Thetransmit sequence may modulo cycle through frequencies that are Of apart(e.g., f1, f1+2 Δf, f1+2 Δf, . . . ) spaced apart in time at intervalst1, t2, t3, etc.

The receive sequence 370 provides the reflection signals in the sameorder of the transmit sequence 368 with small differences in time (e.g.,at r1, r2, r3, . . . ) and frequency. The processing module 50determines distance information based on the small differences in timeand frequency between the receive sequence 370 and the originallytransmitted sequence 368.

FIG. 58 is a schematic block diagram of another embodiment of a Dopplerradar bio-medical unit 10 to provide a distancing radar function todetermine the density of a body object 268 when the body object 268vibrates from an ultrasound signal 372. At least one other bio-medicalunit 10 may provide the ultrasound signal.

The bio-medical unit 10 includes the communication module 48 (e.g., forexternal communications with the communication device and forcommunications with other bio-medical units), the MEMS propulsion 348,the processing module 50, the memory 52, the power harvesting module 46,a MMW frequency adjust 358, a mixer 362, a low noise amplifier 360(LNA), and a power amplifier 356 (PA). The bio-medical unit 10 maycommunicate with other bio-medical units 10 and/or with a communicationdevice 24 to communicate status information and/or commands. Forexample, the bio-medical unit 10 may coordinate with at least one otherbio-medical unit 10 to provide the ultrasound signal 372.

The bio-medical unit 10 may send a transmitted MMW signal 364 to thebody object and receive a reflected MMW signal 366 from the body object.Some of the transmitted MMW signal energy is absorbed by the bodyobject, reflected in other directions, and/or transmitted to otherdirections. Note that the reflections may vary as a function of theultrasound signal where the reflected signals vary according to thedensity of the body object.

The bio-medical unit 10 forms a Doppler radar sequence by varying thefrequency of the transmitted MMW signal 364 over a series oftransmission steps. The bio-medical unit 10 may determine the distanceand density based on the reflected MMW signal 366 in response to theDoppler radar.

The bio-medical unit 10 may receive a command from the communicationdevice 24 to reposition, adjust the MMW frequency, and transmit MMWsignals 364 to perform the Doppler radar function. In anotherembodiment, the communication device 24 may send a command to aplurality of bio-medical units 10 to coordinate the formation of a beamto better pinpoint the body object 268 and determine the density. In yetanother embodiment, the communication device 24 may send a command to aplurality of bio-medical units 10 to coordinate the Doppler radarfunction from two, three or more bio-medical units 10 to triangulate thebody object 268 location based on the distance information.

The processing module 50 may control the MEMS propulsion 348 toreposition the bio-medical unit 10. The processing module 50 maydetermine how to control the MMW frequency adjust 358 to affect thedistance and density information detection based on a command, apredetermination, and/or an adaptive algorithm (e.g., that detectscourse distance ranges at first and fine tunes the accuracy over time).The processing module 50 controls the MMW frequency adjust 358 inaccordance with the determination such that the PA 356 generates thedesired transmitted MMW signal 364. The LNA 360 amplifies the reflectedMMW signal 366 and the mixer 362 down converts the signal such that theprocessing module 50 receives and processes the signal.

FIG. 59 is a schematic block diagram of an embodiment of a controlledrelease bio-medical unit 10 that administers potentially complexmedications. The bio-medical unit 10 includes a MEMS controlled releasemodule 374, the communication module 50 (e.g., for externalcommunications with the communication device and for communications withother bio-medical units), the processing module 50, the memory 52, andthe power harvesting module 46.

The bio-medical unit 10 may communicate with other bio-medical units 10and/or with a communication device 24 to communicate status informationand/or commands. For example, the bio-medical unit 10 may coordinatewith at least one other bio-medical unit 10 to provide theadministration of medications. The processing module 50 may determinewhen and how to administer the medication based on a command, apredetermination, and/or an adaptive algorithm (e.g., that detects localpain).

The MEMS controlled release module 374 may contain materials thatcomprise medications and a unit ID to identify the materials. Theprocessing module 50 may control the MEMS controlled release module 374to mix particular materials to produce a desired medication inaccordance with the unit ID, and the determination of the when and howto administer the medication.

FIG. 60 is a schematic block diagram of an embodiment of a MEMScontrolled release module 374 that controls the formation and deliveryof medications created with materials previously stored in the MEMScontrolled release module 374. The MEMS controlled release module 374may include a MEMS canister 340, a MEMS valve 376, a MEMS pump 378, aMEMS needle 380, MEMS delivery tube 382, and pathways between theelements. The MEMS canister 340 holds one or more materials. The MEMSvalve 376 may control the flow of a material. The MEMS pump 378 mayactively move a material. The MEMS needle 380 may facilitate injectionof the medication. The MEMS delivery tube 382 may facilitate delivery ofthe medication.

The MEMS controlled release module 374 may receive requests and/orcommands from the processing module 50 including request for unit ID,commands to mix 10% material A and 90% material B, a command to injectthe needle, and/or a command to administer the mixture through a MEMSneedle 380 and/or MEMS delivery tube 382.

FIG. 61 is a schematic block diagram of an embodiment of a controlledrelease bio-medical unit 10 system that administers potentially complexmedications. A plurality of bio-medical units 10 transfers (e.g., fromat least one unit to another), mixes, and administers the medications.

A first type of bio-medical unit 10 includes a MEMS controlled releasemodule 374, the communication module 48 (e.g., for externalcommunications with the communication device and for communications withother bio-medical units), the processing module 50, the memory 52, andthe power harvesting module 46. The first type of bio-medical unit 10substantially provides the medication ingredients to a second type ofbio-medical unit 10.

The second type of bio-medical unit 10 includes at least one MEMScontrolled receptacle module 386, a MEMS composition mix and release388, the communication module 48 (e.g., for external communications withthe communication device and for communications with other bio-medicalunits), the processing module 50, the memory 52, and the powerharvesting module 46. The second type of bio-medical unit 10substantially mixes the final medication and administers the medication.

The first and second types of bio-medical unit 10 may communicate withother bio-medical units 10 and/or with a communication device 24 tocommunicate status information and/or commands. For example, the secondtype bio-medical unit 10 may coordinate with at least one first type ofbio-medical unit 10 to provide the administration of medications. Theprocessing module 50 of the second type of bio-medical unit 10 maydetermine when and how to administer the medication based on a command,a predetermination, and/or an adaptive algorithm (e.g., that detectslocal pain). The processing module 50 of the second type of bio-medicalunit 10 may determine which of the plurality of the first type ofbio-medical units 10 contain the required materials based on a unit IDstatus update, a command, and/or a predetermination.

The processing module 50 of the second type of bio-medical unit 10 maysend a command to the plurality of the first type of bio-medical units10 to dock with the second type of bio-medical unit 10 and transfer therequired materials to the MEMS controlled receptacle module 386 of thesecond type of bio-medical unit 10. The processing module 50 of thesecond type of bio-medical unit 10 may control the MEMS composition mixand release 388 to mix the required materials from the plurality offirst type of bio-medical units 10. The processing module 50 of thesecond type of bio-medical unit 10 may control the MEMS composition mixand release 388 to release the mixture in accordance with thedetermination of the when and how to administer the medication.

FIG. 62 is a schematic block diagram of an embodiment of a self-cleaningsampling bio-medical unit 10 where a wave based MEMS cleaner 390facilitates cleaning of a sampling sub-system. The bio-medical unit 10includes the wave based MEMS cleaner 390 for a MEMS sample analyzer 392,a pipette 394, a needle 396, and a MEMS actuator 276. The bio-medicalunit 10 also includes the communication module 48 (e.g., for externalcommunications with the communication device and for communications withother bio-medical units), the processing module 50, the memory 52, andthe power harvesting module 46.

The processing module 50 may determine when to perform a sampling andcleaning of the sampling sub-system based on a command, apredetermination, and/or an adaptive algorithm (e.g., based on a samplehistory). The processing module 50 may precede each sampling with acleaning, follow each sampling with a cleaning, or some combination ofboth.

The processing module 50 may command the wave based MEMS cleaner 390 toclean the components of the sampling sub-system. The wave based MEMScleaner 390 may perform the cleaning with one or methods includingheating, vibrating, RF energy, laser light, and/or sound waves. Inanother embodiment, the bio-medical unit 10 includes a MEMS canister 340with a cleaning agent that is released during the cleaning sequence andexpelled through the needle 396.

The processing module 50 may command the MEMS actuator 276 to applyforce 286 to move the needle 396 into the sampling position where theneedle 396 is exposed to the outside of the bio-medical unit 10 (e.g.,extends into the body). The pipette 394 moves the sample from the needle396 to the MEMS sample analyzer 392.

The MEMS sample analyzer 392 provides the processing module 50 withsample information, which may include blood analysis, pH analysis,temperature, oxygen level, other gas levels, toxin analysis, medicationanalysis, and/or chemical analysis. The processing module 50 may processthe sample information to produce processed sample information. Theprocessing module 50 may send the processed sample information toanother bio-medical unit 10 or to a communication unit 24 for furtherprocessing.

FIG. 63 is a flowchart of an embodiment of a method for controllingpower harvesting within a bio-medical unit 10. The method begins at step418 wherein the processing module 50 of the bio-medical unit 10initializes (e.g., when it is supplied power and wakes up) itself. Forexample, the processing module 50 executes an initialization bootsequence stored in the memory 52. The initialization boot sequenceincludes operational instructions that cause the processing module toinitialize its registers to accept further instructions. Theinitialization boot sequence may further include operationalinstructions to initialize one or more of the communication module 48,the functional module(s) 54 initialized, etc.

The method continues at step 420 where the processing module 50determines the state of the bio-medical unit (e.g., actively involved ina task, inactive, data gathering, performing a function, etc.). Such adetermination may be based on one or more of previous state(s) (e.g.,when the processing module was stopped prior to losing power), an inputfrom the functional module 54, a list of steps or elements of a task,the current step of a MRI sequence, and/or new tasks received via thecommunication module 48.

The method continues at step 422 where the processing module 50determines the bio-medical unit power level, which may be done bymeasuring the power harvesting module 46 output Vdd 56. Note thatvoltage is one proxy for the power level and that other proxies may beutilized including estimation of milliWatt-hours available, a time ofoperation before loss of operating power estimate, a number of CPUinstructions estimate, a number of task elements, a number of tasksestimate, and/or another other estimator to assist in determining howmuch the bio-medical unit 10 can accomplish prior to losing power.Further note that the processing module 50 may save historic records ofpower utilization in the memory 52 to assist in subsequentdeterminations of the power level.

The method continues at step 424 where the processing module 50 comparesthe power level to the high threshold (e.g., a first available powerlevel that allows for a certain level of processing). If yes, the methodcontinues to step 426 where the processing module 50 enables theexecution of H number of instructions. The processing module 50 mayutilize a predetermined static value of the H instructions or a dynamicvalue that changes as a result of the historic records. For example, thehistoric records may indicate that there was an average of 20% morepower capacity left over after the last ten times of instructionexecution upon initialization. The processing module 50 may adjust thevalue of H upward such that the on-going left over power is less than20% in order to more fully utilize the available power each time thebio-medical unit 10 has power.

The method continues at step 428 where the processing module 50 savesthe state in the memory 52 upon completion of the execution of the Hinstructions such that the processing module 50 can start in a state inaccordance with this state upon the next initialization. The method thencontinues at step 430 where the processing module 50 determines whetherit will suspend operations based on one or more of a re-determined powerlevel (e.g., power left after executing the instructions), apredetermined list, a task priority, a task state, a priority indicator,a command, a message, and/or a functional module input. If not, themethod repeats at step 422. If yes, the method branches to step 440where the processing module 50 suspends operations of the bio-medicalunit.

If, at step 424, the power level is not greater than the high threshold,the method continues at step 432 where the processing module 50determines whether the power level compares favorably to a lowthreshold. If not, the method continues a step 440 where the processingmodule 50 suspends operations of the bio-medical unit.

If the comparison at step 432 was favorable, the method continues atstep 434 where the processing module 50 executes L instructions. Theprocessing module 50 may utilize a predetermined static value of the Linstructions or a dynamic value that changes as a result of the historicrecords as discussed previously. For example, the historic records mayindicate that there was an average of 10% more power capacity left overafter the last ten times of instruction execution upon initialization.The processing module 50 may adjust the value of L downward such thatthe on-going left over power is less than 10% in order to more fullyutilize the available power each time the bio-medical unit 10 has power.

The method continues at step 436 where the processing module 50 savesthe state in the memory 52 upon completion of the execution of the Linstructions such that the processing module 50 can start in a state inaccordance with this state upon the next initialization. The method thencontinues at step 438 where the processing module 50 determines whetherit will suspend operations based on one or more of a re-determined powerlevel (e.g., power left after executing the instructions), apredetermined list, a task priority, a task state, a priority indicator,a command, a message, and/or a functional module input. If yes, themethod branches to step 440. If not, the method repeats at step 422.

FIG. 64 is a flowchart illustrating MMW communications within a MRIsequence where the processing module 50 determines MMW communications inaccordance with an MRI sequence. The method begins at step 442 where theprocessing module 50 determines whether the MRI is active based onreceiving MRI EM signals. At step 444, the method branches to step 446or step 448. When the MRI is active, the method continues at step 446where the processing module 50 performs MMW communications as previouslydiscussed.

The method continues at step 448 where the processing module 50determines the MRI sequence based on received MRI EM signals (e.g.,gradient pulses and/or MRI RF pulses as shown in one or more of thepreceding figures). The method continues at step 450 where theprocessing module 50 determines whether it is time to perform receiveMMW communication in accordance with the MRI sequence. For example, theMMW transceiver 138 may receive MMW inbound signals 148 between any ofthe MRI sequence steps. As another example, the MMW transceiver 138 mayreceive MMW inbound signals 148 between specific predetermined steps ofthe MRI sequence.

At step 452 the method branches back to step 450 or to step 454. When itis time to receive, the method continues at step 454 where theprocessing module 50 coordinates the MMW transceiver 138 receiving theMMW inbound signals, which may include one or more of a status request,a records request, a sensor data request, a processed data request, aposition request, a command, and/or a request for MRI echo signal data.The method then continues at step 456 where the processing module 50determines whether there is at least one message pending to transmit(e.g., in a transmit queue). At step 458 the method branches back tostep 442 or to step 460.

At step 460, the processing module 50 determines when it is time totransmit a MMW communication in accordance with the MRI sequence. Forexample, the MMW transceiver 138 may transmit MMW outbound signals 150between any of the MRI sequence steps. As another example, the MMWtransceiver 138 may transmit MMW outbound signals 150 between specificpredetermined steps of the MRI sequence.

At step 462, the method branches to back step 456 or to step 464. Themethod continues at step 464 where the processing module 50 coordinatesthe MMW transceiver 138 transmitting the MMW outbound signals 150, whichmay include one or more of a status request response, a records requestresponse, a sensor data request response, a processed data requestresponse, a position request response, a command response, and/or arequest for MRI echo signal data response. The method then branches backto step 442.

FIG. 65 is a flowchart illustrating the processing of MRI signals wherethe processing module 50 of the bio-medical unit 10 may assist the MRIin the reception and processing of MRI EM signals 146. The method beginsat step 466 where the processing module 50 determines if the MRI isactive based on receiving MRI EM signals 146. The method branches backto step 466 when the processing module 50 determines that the MRI is notactive. For example, the MRI sequence may not start until the processingmodule 50 communicates to the MRI unit that it is available to assist.The method continues to step 470 when the processing module 50determines that the MRI is active.

At step 470, the processing module 50 determines the MRI sequence basedon received MRI EM signals 146 (e.g., gradient pulses and/or MRI RFpulses). At step 472, the processing module receives EM signals 146and/or MMW communication 532 in accordance with the MRI sequence anddecodes a message. For example, the MMW transceiver 138 may receive MMWinbound signals 148 between any of the MRI sequence steps. As anotherexample, the MMW transceiver 138 may receive MMW inbound signals 148between specific predetermined steps of the MRI sequence. In yet anotherexample, the processing module 50 may receive EM signals 146 at anypoint of the MRI sequence such that the EM signals 146 contain a messagefor the processing module 50.

At step 474, the processing module 50 determines whether to assist inthe MRI sequence based in part on the decoded message. The determinationmay be based on a comparison of the assist request to the capabilitiesof the bio-medical unit 10. At step 476, the method branches to step 480when the processing module 50 determines to assist in the MRI sequence.The method continues at step 478 where the processing module 50 performsother instructions contained in the message and the method ends.

At step 480, the processing module 50 begins the assist steps byreceiving echo signals 530 during the MRI sequence. Note the echosignals 530 may comprise EM RF signals across a wide frequency band asreflected off of tissue during the MRI sequence. At step 482, theprocessing module 50 processes the received echo signals 530 to produceprocessed echo signals. Note that this may be a portion of the overallprocessing required to lead to the desired MRI imaging.

At step 484, the processing module 50 determines the assist type basedon the decoded message from the MRI unit. The assist type may be atleast passive or active where the passive type collects echo signal 530information and sends it to the MRI unit via MMW outbound signals 150and the active type collects echo signal information and re-generates aform of the echo signals 530 and sends the re-generated echo signals tothe MRI unit via outbound modulated EM signals (e.g., the MRI unitinterprets the re-generated echo signals as echo signals to improve theoverall system gain and sensitivity).

The method branches to step 494 when the processing module 50 determinesthe assist type to be active. The method continues to step 486 when theprocessing module 50 determines the assist type to be passive. At step486, the processing module 50 creates an echo message based on theprocessed echo signals where the echo message contains information aboutthe echo signals 530.

At step 488, the processing module 50 determines when it is time totransmit the echo message encoded as MMW outbound signals 150 via MMWcommunication in accordance with the MRI sequence. For example, the MMWtransceiver 138 may transmit MMW outbound signals 150 between any of theMRI sequence steps. In another example, the MMW transceiver 138 maytransmit MMW outbound signals 150 between specific predetermined stepsof the MRI sequence.

At step 490, the method branches back to step 488 when the processingmodule 50 determines that it is not time to transmit the echo message.At step 490, the method continues to step 492 where the processingmodule 50 transmits the echo message encoded as MMW outbound signals150.

At step 494, the processing module 50 creates echo signals based on theprocessed echo signals. At step 496, the processing module 50 determineswhen it is time to transmit the echo signals as outbound modulated EMsignals 180 in accordance with the MRI sequence. At step 498, the methodbranches back to step 496 when the processing module 50 determines thatit is not time to transmit the echo signals. At step 498, the methodcontinues to step 500 where the processing module 50 transmits the echosignals encoded as outbound modulated EM signals 180. Note that thetransmitted echo signals emulate the received echo signals 530 withimprovements to overcome low MRI power levels and/or low MRI receiversensitivity.

FIG. 66 is a flowchart illustrating communication utilizing MRI signalswhere the processing module 50 determines MMW signaling in accordancewith an MRI sequence. The method begins at step 502 where the processingmodule 50 determines if the MRI is active based on receiving MRI EMsignals 146. At step 504, the method branches to step 508 when theprocessing module 50 determines that the MRI is active. At step 504, themethod continues to step 506 when the processing module 50 determinesthat the MRI is not active. At step 506, the processing module 50 queuespending transmit messages. The method branches to step 502.

At step 508, the processing module 50 determines the MRI sequence basedon received MRI EM signals 146 (e.g., gradient pulses and/or MRI RFpulses). At step 510, the processing module 50 determines when it istime to perform receive communication in accordance with the MRIsequence. For example, the EM transceiver 174 may receive inboundmodulated EM signals 146 containing message information from any of theMRI sequence steps.

At step 512, the method branches back to step 510 when the processingmodule 50 determines that it is not time to perform receivecommunication. At step 512, the method continues to step 514 where theprocessing module 50 directs the EM transceiver 174 to receive theinbound modulated EM signals. The processing module 50 may decodemessages from the inbound modulated EM signals 146 such that themessages include one or more of a echo signal collection assist request,a status request, a records request, a sensor data request, a processeddata request, a position request, a command, and/or a request for MRIecho signal data. Note that the message may be decoded from the inboundmodulated EM signals 146 in one or more ways including detection of theordering of the magnetic gradient pulses, counting the number ofgradient pulses, the slice pulse orderings, detecting small differencesin the timing of the pulses, and/or demodulation of the MRI RF pulse.

At step 516 the processing module 50 determines if there is at least onemessage pending to transmit (e.g., in a transmit queue). At step 518,the method branches back to step 502 when the processing module 50determines that there is not at least one message pending to transmit.At step 518, the method continues to step 520 where the processingmodule 50 determines when it is time to perform transmit communicationin accordance with the MRI sequence. For example, the EM transceiver 174may transmit outbound modulated EM signals 180 between any of the MRIsequence steps. In another example, the EM transceiver 174 may transmitthe outbound modulated EM signals 180 between specific predeterminedsteps of the MRI sequence. In yet another example, the EM transceiver174 may transmit the outbound modulated EM signals 180 in parallel withspecific predetermined steps of the MRI sequence, but may utilize adifferent set of frequencies unique to the EM transceiver 174.

At step 522, the method branches back to step 520 when the processingmodule 50 determines that it is not time to perform transmitcommunication. At step 522, the method continues to step 524 where theprocessing module 50 directs the EM transceiver 174 to prepare theoutbound modulated EM signals 180 based on the at least one messagepending to transmit. The processing module 50 may encode messages intothe outbound modulated EM signals 180 such that the messages include oneor more of a status request response, a records request response, asensor data request response, a processed data request response, aposition request response, a command response, and/or a request for MRIecho signal data response. The method branches back to step 502.

FIG. 67 is a flowchart illustrating the communication of records wherethe processing module 50 of the bio-medical unit 10 determines toprovide medical records. The method begins at step 566 where theprocessing module 50 determines if receiving MMW communication isallowed. The determination may be based on one or more of a timer, acommand, available power, a priority indicator, and/or interferenceindicator. For example, the MMW transceiver 138 may receive MMW inboundsignals 148 for a 500 millisecond window every 3 minutes.

At step 568, the method branches back to step 566 when the processingmodule 50 determines that receiving MMW communication is not allowed. Atstep 568, the method continues to step 570 where the processing module50 directs the MMW transceiver 138 to receive MMW inbound signals 148.The processing module 50 may decode messages from the MMW inboundsignals 148 such that the decoded message include one or more of astatus request, a records request, a sensor data request, a processeddata request, a position request, a command, and/or a request for MRIecho signal data.

At step 572, the processing module 50 determines whether to providerecords in response to the records request based in part on the decodedmessage. The determination may be based on a comparison of the recordsrequest to the capabilities of the bio-medical unit 10. Note thatrecords may include patient history, medications, alerts, allergies,personal information, contact information, age, weight, test results,etc.

At step 576, the method branches to step 578 when the processing module50 determines to provide records. At step 576, the method continues tostep 576 when the processing module 50 determines to not providerecords. At step 576, the processing module 50 performs otherinstructions contained in the message. The method ends.

At step 578, the processing module 50 determines when it is time totransmit. The determination may be based on a timer, a command,available power, a priority indicator, a timeslot, and/or interferenceindicator. At step 580, the method branches back to step 578 when theprocessing module 50 determines it is not time to transmit. At step 580,the method continues to step 582 when the processing module 50determines it is time to transmit.

At step 582, the processing module 50 determines the format to providerecords. The format determination may be based on one or more of amemory lookup, a command, available power, the type of recordsrequested, an access ID of the requester, a priority indicator, a levelof detail indicator, and/or a freshness indicator. Note that the formatmay include records format as stored in the bio-medical unit memory(e.g., all or a portion of the records) or a uniform resource locator(URL) to link to another memory in one or more of the service provider'scomputer, the database, and/or the server.

At step 584, the method branches to step 588 when the processing module50 determines the format to provide records is the URL format. At step584, the method continues to step 586 where the processing module 50prepares the records format response message based on recordsinformation retrieved from the bio-medical unit memory 52. The methodbranches to step 590.

At step 588, the processing module prepares the URL format responsemessage based on retrieving the URL from the bio-medical unit memory 52.At step 590, the processing module 50 transmits the response messageencoded as MMW outbound signals 150. For example, the bio-medical unit10 transmits the response message via a second wireless communicationsmedium including one or more of infrared signals, ultrasonic signals,visible light signals, audible sound signals, and/or EM signals via oneor more of the functional modules.

FIG. 68 is a flowchart illustrating the coordination of bio-medical unittask execution where the processing module 50 determines and executestasks with at least one other bio-medical unit 10. The method begins atstep 592 where the processing module 50 determines if communication isallowed. The determination may be based on one or more of a timer, acommand, available power, a priority indicator, an MRI sequence, and/orinterference indicator.

At step 594, the method branches back to step 592 when the processingmodule 50 determines that communication is not allowed. At step 594, themethod continues to step 596 when the processing module 50 determinesthat communication is allowed. At step 596, the processing module 50directs the communication module 48 to communicate with a plurality ofbio-medical units 10 utilizing RF and/or MMW inbound and/or outboundsignals. The processing module 50 may decode messages from the RF and/orMMW inbound and/or outbound signals inbound signals. At step 598, theprocessing module 50 determines if communications with the plurality ofbio-medical units 10 is successful based in part on the decodedmessages.

At step 600, the method branches back to step 592 when the processingmodule determines that communications with the plurality of bio-medicalunits 10 is not successful. Note that forming a network with the otherbio-medical units 10 may be required to enable joint actions. At step600, the method continues to step 602 when the processing module 50determines that communications with the plurality of bio-medical units10 is successful.

At step 602, the processing module 50 determines the task and taskrequirements. The task determination may be based on one or more of acommand from a parent bio-medical unit 10, external communications, apreprogrammed list, and/or in response to sensor data. The taskrequirements determination may be based on one or more of the task, acommand from a parent bio-medical unit 10, external communications, apreprogrammed list, and/or in response to sensor data. Note that thetask may include actions including one or more of drilling, moving,sawing, jumping, spreading, sensing, lighting, pinging, testing, and/oradministering medication.

At step 604, the processing module 50 determines the control mode basedon one or more of a command from a parent bio-medical unit 10, externalcommunications, a preprogrammed list, and/or in response to sensor data.Note that the control mode may include autonomous, parent (bio-medicalunit), server, and/or peer.

At step 606, the processing module 50 determines if task executioncriteria are met based on sensor data, communication with otherbio-medical units 10, a command, a status indicator, a safety indicator,a stop indicator, and/or location information. Note that the taskexecution criteria may include one or more of safety checks, positioninformation of the bio-medical unit 10, position information of otherbio-medical units 10, and/or sensor data thresholds.

At step 608, the method branches back to step 606 when the processingmodule 50 determines that the task execution criteria are not met. Atstep 608, the method continues to step 610 when the processing module 50determines that the task execution criteria are met. At step 610, theprocessing module 50 executes a task element. A task element may includea portion or step of the overall task. For example, move one centimeterof a task to move three centimeters.

At step 612, the processing module 50 determines if task exit criteriaare met based on a task element checklist status, sensor data,communication with other bio-medical units 10, a command, a statusindicator, a safety indicator, a stop indicator, and/or locationinformation. Note that the task exit criteria define successfulcompletion of the task.

At step 614, the method branches back to step 592 when the processingmodule 50 determines that the task exit criteria are met. In otherwords, the plurality of bio-medical units 10 is done with the currenttask and is ready for the next task. At step 614, the method continuesto step 616 when the processing module 50 determines that the task exitcriteria are not met.

At step 616, the processing module 50 directs the communication module48 to communicate with the plurality of bio-medical units 10 utilizingRF and/or MMW inbound and/or outbound. The processing module 50 maydecode messages from the RF and/or MMW inbound and/or outbound signalsinbound signals. Note that the messages may include information inregards to task modifications (e.g., course corrections). At step 618,the processing module 50 determines if communications with the pluralityof bio-medical units 10 is successful based in part on the decodedmessages.

At step 620, the method branches back to step 592 when the processingmodule determines that communications with the plurality of bio-medicalunits is not successful (e.g., to potentially restart). Note thatmaintaining the network with the other bio-medical unit may be requiredto enable joint actions. At step 620, the method continues to step 622when the processing module determines that communications with theplurality of bio-medical units is successful.

At step 622, the processing module 50 determines task modifications. Thetask modifications may be based on one or more of a command from aparent bio-medical unit 10, and/or external communications. The taskmodifications determination may be based on one or more of the task, acommand from a parent bio-medical unit 10, external communications, apreprogrammed list, and/or in response to sensor data. The methodbranches back to step 606 to attempt to complete the current task.

As may be used herein, the terms “substantially” and “approximately”provides an industry-accepted tolerance for its corresponding termand/or relativity between items. Such an industry-accepted toleranceranges from less than one percent to fifty percent and corresponds to,but is not limited to, component values, integrated circuit processvariations, temperature variations, rise and fall times, and/or thermalnoise. Such relativity between items ranges from a difference of a fewpercent to magnitude differences. As may also be used herein, theterm(s) “coupled to” and/or “coupling” and/or includes direct couplingbetween items and/or indirect coupling between items via an interveningitem (e.g., an item includes, but is not limited to, a component, anelement, a circuit, and/or a module) where, for indirect coupling, theintervening item does not modify the information of a signal but mayadjust its current level, voltage level, and/or power level. As mayfurther be used herein, inferred coupling (i.e., where one element iscoupled to another element by inference) includes direct and indirectcoupling between two items in the same manner as “coupled to”. As mayeven further be used herein, the term “operable to” indicates that anitem includes one or more of power connections, input(s), output(s),etc., to perform one or more its corresponding functions and may furtherinclude inferred coupling to one or more other items. As may stillfurther be used herein, the term “associated with”, includes directand/or indirect coupling of separate items and/or one item beingembedded within another item. As may be used herein, the term “comparesfavorably”, indicates that a comparison between two or more items,signals, etc., provides a desired relationship. For example, when thedesired relationship is that signal 1 has a greater magnitude thansignal 2, a favorable comparison may be achieved when the magnitude ofsignal 1 is greater than that of signal 2 or when the magnitude ofsignal 2 is less than that of signal 1.

The present invention has also been described above with the aid ofmethod steps illustrating the performance of specified functions andrelationships thereof. The boundaries and sequence of these functionalbuilding blocks and method steps have been arbitrarily defined hereinfor convenience of description. Alternate boundaries and sequences canbe defined so long as the specified functions and relationships areappropriately performed. Any such alternate boundaries or sequences arethus within the scope and spirit of the claimed invention.

The present invention has been described above with the aid offunctional building blocks illustrating the performance of certainsignificant functions. The boundaries of these functional buildingblocks have been arbitrarily defined for convenience of description.Alternate boundaries could be defined as long as the certain significantfunctions are appropriately performed. Similarly, flow diagram blocksmay also have been arbitrarily defined herein to illustrate certainsignificant functionality. To the extent used, the flow diagram blockboundaries and sequence could have been defined otherwise and stillperform the certain significant functionality. Such alternatedefinitions of both functional building blocks and flow diagram blocksand sequences are thus within the scope and spirit of the claimedinvention. One of average skill in the art will also recognize that thefunctional building blocks, and other illustrative blocks, modules andcomponents herein, can be implemented as illustrated or by discretecomponents, application specific integrated circuits, processorsexecuting appropriate software and the like or any combination thereof.

1-20. (canceled)
 21. An integrated circuit (IC) for incorporation in aclothing fabric, the IC comprises: a power harvesting module configuredto convert a radio frequency (RF) signal into a supply voltage; acommunication module configured, when powered by the supply voltage, to:convert an inbound wireless signal into an inbound symbol stream;convert an outbound symbol stream into an outbound wireless signal; aprocessing module configured, when powered by the supply voltage, to:convert the inbound symbol stream into a bio-medical function; convert abio-medical response into the outbound symbol stream; a functionalmodule configured, when powered by the supply voltage, to: perform thebio-medical function; and when the bio-medical function is a monitoringfunction, generate the bio-medical response.
 22. The IC of claim 21,further comprising: an IC package housing the IC, wherein the IC packageincludes a fabric adhering mechanism
 23. The IC of claim 22 wherein thefabric adhering mechanism comprises at least of: an eyelet forfacilitating sewing the IC into the clothing fabric; a hook forfacilitating sewing the IC into the clothing fabric; a notch forfacilitating sewing the IC into the clothing fabric; and a fabricadhesive for facilitating gluing the IC into the clothing fabric. 24.The IC of claim 21 further comprises: an encapsulant for encapsulatingthe IC package.
 25. The IC of claim 21, wherein the bio-medical functionfurther comprises at least one of: an image capture function; a movementcapture function; a sound capture function; a topical treatmentfunction; and an electronic stimulation function.
 26. The IC of claim21, wherein the power harvesting module comprises at least one of: anelectromagnetic signal to voltage conversion module; an RF signal tovoltage conversion module; a motion to voltage conversion module; alight to voltage conversion module; and a heat to voltage conversionmodule.
 27. The IC of claim 26, wherein the electromagnetic signal tovoltage conversion module comprises at least one of: an array ofinductors and a rectifying circuit module to produce the supply voltagefrom the electromagnetic signal; and an array of Hall-effect devices andthe rectifying circuit module to produce the supply voltage from theelectromagnetic signal.
 28. An article of clothing comprises: a clothingfabric; and a plurality of bio-medical units integrated with theclothing fabric, wherein a bio-medical unit of the plurality ofbio-medical units includes: a power harvesting module operable toconvert radio frequency (RF) signals into a supply voltage; acommunication module operable, when powered by the supply voltage, to:convert an inbound wireless signal into an inbound symbol stream; andconvert an outbound symbol stream into an outbound wireless signal; aprocessing module operable, when powered by the supply voltage, to:convert the inbound symbol stream into a bio-medical function; andconvert a bio-medical response into the outbound symbol stream; afunctional module operable, when powered by the supply voltage, to:perform the bio-medical function; and when the bio-medical function is amonitoring function, generate the bio-medical response.
 29. The articleof clothing of claim 28 wherein the plurality of bio-medical units areintegrated into the clothing fabric by adhering the plurality ofbio-medical units into seams of the clothing fabric.
 30. The article ofclothing of claim 28, wherein the clothing fabric comprises: a pluralityof pouches for housing at least some of the bio-medical units.
 31. Thearticle of clothing of claim 28, further comprising: a die supporting atleast one of the power harvesting module, the processing module, thecommunication module, and the functional module; and an IC packagehousing the IC.
 32. The article of clothing of claim 31, wherein the ICpackage further comprises: a fabric adhering mechanism that includes atleast of: an eyelet for facilitating sewing the IC into the clothingfabric; a hook for facilitating sewing the IC into the clothing fabric;a notch for facilitating sewing the IC into the clothing fabric; and afabric adhesive for facilitating gluing the IC into the clothing fabric.33. The article of clothing of claim 28, wherein the bio-medical unitfurther comprises: an encapsulant for encapsulating the IC package. 34.The article of clothing of claim 28, wherein the bio-medical functionfurther comprises at least one of: an image capture function; a movementcapture function; a sound capture function; a topical treatmentfunction; and an electronic stimulation function.
 35. The article ofclothing of claim 28, wherein the power harvesting module comprises atleast one of: an electromagnetic signal to voltage conversion module; anRF signal to voltage conversion module; a motion to voltage conversionmodule; a light to voltage conversion module; and a heat to voltageconversion module.
 36. The article of clothing of claim 35, wherein theelectromagnetic signal to voltage conversion module comprises at leastone of: an array of inductors and a rectifying circuit module to producethe supply voltage from the electromagnetic signal; and an array ofHall-effect devices and the rectifying circuit module to produce thesupply voltage from the electromagnetic signal.
 37. A method for aexecuting a bio-medical application by a wireless communication device,the method comprising: transmitting a continuous wave (CW) signal for apredetermined period of time, wherein a power harvesting module of abio-medical unit of a plurality of bio-medical units integrated into aclothing fabric converts the CW signal into a supply voltage; afterexpiration of the predetermined period of time, transmitting a radiofrequency (RF) signal for executing the bio-medical application,including: converting the RF signal into an inbound symbol stream;converting the inbound symbol stream into a bio-medical command;performing the bio-medical command and, when commanded, generating abio-medical response; converting the bio-medical response into anoutbound symbol stream; and converting the outbound symbol stream intoan outbound RF response signal; and receiving the RF response signal.38. The method of claim 37 further comprising: receiving a request forre-transmission of the CW signal as the RF response signal.
 39. Themethod of claim 37 further comprising: instructing the power harvestingmodule to also convert the RF signal into the supply voltage.
 40. Themethod of claim 37 further comprising: after sending the RF signal,resume transmitting the CW signal; indicating a time window for when thebio-medical unit is to transmit the RF response signal; and during thetime window, stop transmitting the CW signal.